Louis Kervran: Biological Transmutations and Modern Physics~
1982, English translation

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***Biological Transmutations and Modern
Physics***

by **Louis Kervran**

**[ [PDF](ModPhys2.pdf)
]**

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Maloine S.A. Publisher, Paris (1982)   
ISBN 2-224-00831-7

**[Transcribed from an unpublished manuscript
of the English translation -- a few paragraphs are
unreadable in my photocopy of the manuscript, and some
sections are missing.]**

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**Table of Contents**

**Introduction**

**Part I ~ Experimental Proofs of the Existence
of the Biological Transmutation Phenomenon**

**[Chapter 1 ~ General Overview](#p1c1)**

**[Chapter 2 ~ Experiments
Proving Biological Transmutation](#p1c2)**   
**(1) Historical summary ~ (2) A few experiments made after
1974 ~ (3) Research by J. E. Zundel ~ (4) Study of the
variation of calcium in oat seedlings during germination in
twice-distilled water ~ (5) Comments on a study by Zundel on
the increase in calcium in oats during germination in twice
distilled water ~ (6) Comments on some experiments ~ (7)
Reservations on some analytical techniques**

**[Chapter 3 ~ Additional
Information on Physical Phytochemistry During Germination](#p1c3)**
  
**(1) Summary of the germinating phases of grain cereals ~
(2) Average curve of the increase in calcium of oats after
germination**

**[Chapter 4 ~ Photosynthesis](#p1c4)**
  
**(1) Effects of artificial lighting in photosynthesis for
the study of transmutation by cereal plants ~ (2)
Photosynthesis limited to traditional aspects ~ (3)
Photosynthesis cycle of Hatch and Slack**

**[Chapter 5 ~ The Devils
Advocate](#p1c5)**

**[Chapter 6 ~ Problems Related
to Phosphorus, Complexity of Phytoanalysis](#p1c6)**

**[Chapter 7~ How to Correctly
Duplicate a Typical Experiment in Biological
Transmutations](#p1c7)**   
**(1) Study of calcium variation in cultivated oats ~ (2)
Biological conditions ~ (3) Conclusions**

**Chapter 8 [ Missing ]~ Mass Spectrometer
Analysis**   
**(1) Conclusion**

**Part II ~ Explanation of the Phenomena By
Modern Physics, Theoretical Study**

**[Chapter 1 ~ Explanations From
The Atomic Particle Theory](#p1c1)**

**[Chapter 2 ~ A Few Examples Of
Theories Proposed By Physicists](#p2c2)**   
**(1) Process developed by a US Army scientific department ~
(2) L. Romanis contribution ~ (3) Theory proposed by A.
Dubrov ~ (4) A few interesting points of view expressed by
physicists ~ (5) O. Costa de Beauregards theory**

**[Chapter 3 ~ Addenda To The
Theoretical Study Of Low Energy Interactions Applied To
Particular Transmutations](#p2c3)**   
**(1) Effective section ~ (2) Isotopic variations ~ (3)
Nature operates at a finer level than man ~ (4) Changes in
our understanding of some aspects of physics and weakness of
this understanding ~ (5) A few arguments against a unified
theory for electromagnetic and weak interactions ~ (6)
Intermediary vector bosons**

**Appendix 1 [ Missing ] ~ Geology**

**Appendix II [ Missing ] ~ An Extrapolation:
(1) Crying wolf ~ (2) One must rethink the concept of energy
in living matter ~ (3) Non-electromagnetic energies in
living matter ~ (4) Parapsychology and hypothalamus ~ (5)
Germination procedure for oat seeds with no external
addition of calcium**

**Appendix III [ MIssing ]~ Weinberg Theory
Summary: A few definitions**

**Bibliography [Missing ]**

---

**Introduction**

The present work consists of two distinctly
separate parts.

Firstly, I cite some new experiments, completed
since the appearance of my book which was submitted for
printing in 1974 and which was published in 1975: *Biological
Evidence of Low Energy Transmutations* (Maloine
Publications, Paris, 1975). That book was concerned with a
comprehensive view of a phenomenon which calls for precise
analysis. This led me to limit research to a single aspect: to
show that, however precisely one studies the germination and
cultivation of a plant, comparative analysis of the seed and
of the whole plant coming from a seed as nearly identical as
possible, without the possibility of having an external
contribution from some mineral, show that there is, in a very
significant way, a "creation of matter", "appearance" of an
element, thus an atomic "transmutation", which is confirmed by
various methods of analysis utilizing the most sensitive, most
specific, and most modern techniques of physics.

I limited myself to studying variations in the
amount of calcium without studying what element or elements
could have given rise to this variation by this atomic
modification. Such a research project could be very complex
indeed because there could be several origins as a function of
the species of vegetation (or animals, higher or lower, even
microbial), confirmed experimentally: the calcium could come
from potassium, from magnesium, or from silicon, by either
separate or simultaneous reactions. So we have there a
completely different point of view. I wished to limit the
subject so as to produce irrefutable evidence that there is
indeed in life forms a phenomenon which too many people have
wished to deny for untenable reasons. I will demonstrate it
and limit the study to the variation of calcium in a single
cultured species, oats, in order to firmly show that such
experiments can be reproduced, that the conclusions result
from hundreds of experiments and thousands of analyses and are
amply demonstrated. Accordingly, we are concerned here with an
objective contribution [apport] and not with a subjective
deduction.

Next is shown an example of explanation placing
itself in the framework of the most recent atomic theory, that
of "neutral currents" already sketched in the last chapter of
my work of 1975 cited previously which included a "Terminal
Note" of 1974 from the great French physicist of international
stature, Oliver Costa de Beauregard, theory confirmed by a
specialist in elementary particles, Bernard dEspagnat,
director of the Laboratory of Particle Physics of Paris. We
are concerned here with a very young branch of nuclear physics
which is evolving very rapidly and I cannot even dream of
following its most recent discoveries, out-of-date before
being printed. I will make a very condensed review of the
situation in this science toward the beginning of 1981,
keeping in mind that the authors of basic principles of this
theory received the Nobel Prize for Physics at the end of
1979. That is to say that this aspect of weak energy
interactions is now adopted by International Science. This
section seemed indispensable to me because too many
physicists, and along with them scientists from various other
disciplines, consider transmutations only a phenomenon which
recapitulates strong interactions. Blinded by the atomic bomb,
they have not thought that there were also low energy
transmutations, from which they produce a stubborn and sterile
opposition to my work.

Here I give only the current status of a theory
that is rapidly evolving. It will probably be superceded in a
few years, or more or less revised, but it is necessary to
show that it is not rejected by nuclear physics avant-garde,
that if I have been correct too soon (for them), nevertheless
the transmutation of certain elements by a biological action
is in no way mystical; it is an explicable reality in
conformance with a theory which is now very classical and
official and still ignored by too many scientists. Here they
will find an incentive to study more deeply this new entry
into particle physics, unfortunately not possible to lay out
in detail because new facts are turning up all the time: in
1980 did not one come, does it not seem, to produce evidence
that neutrinos (basic particles of weak energy transmutations)
have weight when all calculations prior to 1980 were conducted
under the hypothesis of a null mass?

I will show, then, that:

(1) transmutations by living matter and with
weak energy, do indeed exist; and   
(2) that they fall within the framework of classic theory of
weak energy interactions.

---

**Part I**

**Experimental Demonstrations of the
Existence of the Phenomenon of Biological
Transmutation**

"It is absolutely impossible to prove a priori the
impossibility of a fact" (Bergson).

**Chapter 1**

**General Overview**

Let us start out by considering a statement by
Claude Bernard which will always be timely: "The experimental
method consists in revising theorems and not in preserving
them. Theory must adopt to nature but nature need not adapt to
theory". Pasteur, on his death bed, confirmed to Renon:
"Bernard was correct when he said: 'When one encounters a fact
which conflicts with a dominant theory, one must accept the
fact and abandon the theory, even though the latter is
supported by influential people and widely accepted'.

Experience has taught me just how close to truth
was Claude Bernard. To talk about the transmutation of matter
in a biological environment seemed to be a risky bet for
certain theoreticians. In practice, however, it is certain
that this phenomenon had appeared more or less clearly to a
number of observers at every intellectual level. Many
professionals in various disciplines have expressed this
openly. It seems that the irrefutable facts were there known
to everyone, but refused acknowledgment by certain persons
because of their timidity. Or perhaps, having indeed seen the
facts, they still did not dare say so".

Thus, between the two world wars of the 20th
century, a Swiss agronomist, Pfeiffer, who emigrated to the
USA, called attention to the fact that a gardener perceived
that his land lacked calcium when his lawns were covered with
daisies (or with buttercups). It is obvious to everyone. The
turf is composed primarily of rye-grass, a calcareous plant
--- one which consumes calcium --- which is therefore an
indispensable component of the soil in order for it to grow
well. By contrast, daisies and buttercups, etc., are
calcifugous plants: their development is not satisfactory
unless the soil is acid, almost completely without calcium.
Having had the curiosity to analyze the ashes of the daisies,
however, Pfeiffer discovered that these plants, which fled
from calcarious soil , were rich in calcium. Could it be that
a balance is established, something like a symbiosis between
rye-grass and daisy, precisely because the daisy produced in
the soil, by developing and dying, the calcium needed for a
good growth of rye-grass? He did not push his research any
further, simply accepting the assumption that in this soil,
from which the calcareous component was sucked up by the
rye-grass carried off after having mowed the lawn, there was a
creation of calcium by the daisies. That was scarcely orthodox
and he did not dare state that position openly --- to protect
his career, perhaps?

A discovery of the same order may be credited to
horticulturists who were intensively growing heather land
flowers for resale. The calcifugous plants (azaleas, etc.) did
very well in a "good" heather land for several years. Then,
little by little, the culture declined and it was necessary to
abandon plantations of this sort or to renovate the arable
soil. In horticulture we find eminent engineers and superior
technicians who thought that the solution to their
disappointments could only be realized by chemical analysis of
their land. Accordingly, they discovered that this land,
originally acid, had become basic, or occasionally neutral,
clearly richer in calcareous substance, even though taking
into consideration that they were growing calcifugous plants
they had certainly avoided laying on any calcareous fertilizer
whatsoever. Where did this undesirable element come from?

Did they visualize an elevating of calcium from
the subsoil by capillarity? But certain cultivation, from all
evidence, was not on a calcareous subsoil. To get to the
bottom of this they removed the stratum of arable soil right
up to the subjacent layer of impermeable clay, laid out some
sheets of plastic on this layer to insure that there would be
no reestablishment of calcareous substance by any sort of
unfortunate migration, vertical or horizontal, and then
covered the plastic over again with a layer of good heather
land soil which had been carefully analyzed.

After a few years there was a repetition of the
preceding observations: without bringing in any calcareous
substance the soil was enriched in calcium. Having become
acquainted with my studies they asked me at a conference to
explain to them the mechanism by which I thought: in my
opinion there had been production of calcium by the rootlets
remaining with each uprooting and accordingly absorbed by
osmosis by the roots. What other explanation can there be?

But it does not suffice to deduce and affirm. It
must be demonstrated scientifically by systematic and rigorous
experiments. I did that. One will find in the present work
irrefutable demonstrations that certain calcifugous plants
produce clear evidence of calcium in clearly measurable
quantities, absolutely without any possibility of error,
excluding the possibility of a change in solar radioactivity.
Agronomists who know how to observe and whose judgment is not
obliterated by obsolete dogma clearly admitted this since it
was a phenomenon well known to their profession for some
decades, although still formulated with too much timidity.

I should also cite results of analyses given by
semi-official Tables of Nutrients, often referred to under the
name of Tables of L. Randoin, accounting services of the
National Ministry of Education. They do not make precise
distinctions for different varieties; they only give averages
for genera and species and sometimes the analyses --- without
precise methods --- have been borrowed by different authors.
Lets take the case of the soybean. It gives the composition of
the seed. We give here only the percentage of calcium, the
element which will mainly be studied in this book.

It gives: 280 mg per 100 gr of material. In soya
sprouts, it indicates for Ca: 48 mg per 100 gr

These values are given without precise
description of cultivation and methods of analysis (all
chemical at this time). Accordingly, they cannot be compared
without some calculations. The seed is given with a percentage
of water of 7.5 gr per 100 gr of material, while in the shoots
there were 86 gr of water per 100 gr of material. From this
fact, proceeding from equivalent dryness (that of the seed
being the starting point), the percentage of Ca, which is 48
mg (for 86 gr water) would be 554 mg in lieu of 280 in the
seed, for 7.5 gr of water. The increase in the sprouts then,
is in the neighborhood of 96%, which is clearly in the order
of magnitude of the increase of Ca in germinated oats, as we
will see further on.

So then, did the plants only accomplish a
chemical exchange? Or did they accomplish alchemy? This word
generated fear and was rejected with horror by scientists
subjugated by concepts of physics much too recently
established to be lightly set aside.

Too many physicists believed devoutly in laws
which they considered to be general, universal, and applicable
under all circumstances. The evidence of facts which could not
be explained by their theories, which could not even come
close to disturbing the pattern of their professional
commitments.

For them it was actually profane to think that a
transmutation could be accomplished by a living organism. This
was evidence of feeble-mindedness... Indeed, people were
obliged to admit that transmutation phenomena could be produce
din nature and in the second third of the 20th century we even
succeeded in reproducing radioactive transmutations (1935). At
the same time, non-radioactive transmutations had been
artificially produced since 1919. Then it was in 1945 that the
atomic bomb had a formidable impact on the thinking of
physicists, blocking all critical thinking in far too many of
them.

As a result of my previous studies, first
published in 1936, I was officially appointed at the national
level, to follow closely the creation of nuclear physics
essentially to promote security measures to prevent biological
effects of atomic radiations. For a period of 20 years, up to
my retirement, I retained these functions, periodically
reconfirmed by council orders. Thus, I was at the interface
between physics and biology before the emergence of atomic
energy. As a matter of fact, I was present at the birth of
nuclear physics and was able to follow all its developments.
Because of my official duties no laboratory classified secret
was closed to me.

In 1936 the author published the first results
of his experimental research showing that the human body does
not follow Ohms law, that its resistance varies as an inverse
function of voltage applied, which explains values which are
not independent of voltage output from the ohmmeters employed
(for example, see *Outlines of Industrial Medicine* by
Prof Simonin, Maloine Publ., Paris)

These researches were interrupted by the second
world war, and in 1940, the author was arrested for
Resistance, incarcerated at Fort Montluc in Lyon, and found
guilty without appeal. Having served his time, he participated
in setting up the Southeast Resistance. In 1944 he was
appointed Prefect by the general assembly of the Committees of
Liberation of Savoy, and then given the duties of Regional
Prefect of Savoy-Dauphine. He received the Medal of the
Resistance. Shortly thereafter he re-entered his original
cadre as director in charge of scientific functions at Paris
for a period of 20 years.

That is why I assessed the value of what was
obtained with certainty in this discipline but also the limits
of our knowledge in accordance with the trend of the times. It
seemed to me that, primarily in biology, but also in physics,
unverified data were being assumed by inference
[extrapolation], even though they were contradicted by certain
observations which oriented me along channels which were being
ignored completely by most atomic physicists who were unable
to question their own understanding.

"You should discuss the matter with your peers",
they once said to me. But who were my peers? As a function of
my duties I was also named "director of conferences" at the
University of Paris. That was, in fact, the official
designation, as represented in the Deans teaching
directories. Accordingly, were my pers these tens of thousands
of teachers on our faculties? Could I put myself in the same
structure as tens of thousands of professors of higher
education when I had a unique function in France, recognized
by an official appointment (and even several inter-ministry
groups representing all the ministries scientifically
interested in atomic energy, by one title or another, also
appointed me to represent them in the inter-ministerial
commissions which were obliged to take regulatory actions in
this domain requiring expertise in both biology and atomic
physics (Atomic Population Protection, Public Health, etc.)

Indeed I knew, having been a member of the
examining committee at the doctorate level (before the title
was degraded by creating the "third level doctorate") how
impossible it is to avoid that in a huge corps of tens of
thousands of members some diplomas slide by that are really
below any standard. If they are, in the overall, about one
quarter of mediocre, about one-half average, and one quarter
good from which one can select out a true elite, several
working together --- I had no practical way of deciding who
was a member of this elite group, and, in any case, it was not
up to me to make such a necessarily subjective and arbitrary
decision. I make no claim to be universal but I would
recognize who in the national scene had an "international
value" and that my duties enabled me to consult, moreover, if
need be, on any detail, in order to achieve a synthesis, which
is becoming more and more difficult to realize because of
intensified specialization which no longer leaves a place for
any but the "analysts", and rejects the "synthesists".

In 1950 I began to publish the first results of
my research showing that living matter, both animals and
plants, accomplished transmutations of elements. These
transmutations were observed in man, animals, microorganisms
and plants. They were transmutations which, from all evidence,
had nothing in common with high energy transmutations which
are the only ones which the majority of atomic physicists are
inclined to accept and the only interactions which scientists
in general accept without any reservations. However, this did
not block official acknowledgment of the value of my work and
in 1964 I received recognition with a Legion of Honor ribbon.

I has experimentally produced irrefutable
evidence of the existence of facts which could not be
explained solely in terms of "chemical" biology. I had
evidence of phenomena of non-radioactive atomic physics which
could not be explained by classical atomic physics of this
time. But I had established that the only thing which could
account for the observed results was a nuclear physics which
remained to be more precisely developed and which I was the
first to express in clearly stated formulae of nuclear
reactions.

**(1) "Life Is Nothing But Chemistry" ~**

To a greater and greater extent, throughout the
19th century and then more fully in the 20th century we have
been taught that all biological phenomena depend upon chemical
reactions. I certainly do not deny the truth of this obvious
situation. But that is only part of the truth. If one desires
to reduce everything to chemistry one is led into serious
errors with respect to human, animal and vegetal biology.

In advanced agricultural schools and faculties
of science and medicine one still sees it advanced with
laughable self-confidence that, as an example, water is always
water; there is only one formula for water: H2O
(which should be expressed less rigidly, for we can have H3O4,
etc, and the diversity of snow crystals shows that... but I do
not wish to deal with chemistry). Take some grapes which have
been slowly dried out, then soak them in pure water which
bears a trace of mineral or organic matter. Everyone knows
that grapes thus reconstituted do not taste the same as and
have other properties than fresh grapes. Likewise, chemical
analysis shows that composition with respect to carbohydrates,
lipids and proteins differs between fresh and dried grapes and
that these differences are not simply a matter of water
evaporation. All nutritionists who are not blinded by dogma
recognize this and take it into account.

Otherwise stated, simplified chemistry fails to
account for modifications of molecular structure resulting
from a physical phenomenon such as gradual evaporation. But
that is nothing more than an aspect which can be easily
explained, for example, by classic procedures of
stereochemistry. In my publications and in conferences I have
called attention to the transformation that the organism
forces on carbohydrates to generate lipids (one can fatter a
pig on nothing but potatoes which are rich in carbohydrates
but poor in lipids). In a diet nothing will suppress lipids
for people who have a tendency to fatten on carbohydrates. It
appears that their organism provokes this transformation into
lipids as a result of some metabolic disturbance which may
have a number of glandular or alimentary causes such as a
magnesium deficit, etc. One does not cure the effects by
forgetting the cause. And this is true throughout biology. We
should remember campaigns against food substances rich in
cholesterol, a normal product of physiological catabolism, If
they are not provided in the diet the organism will,
nevertheless, fabricate them. The unbalance is to be
discovered in the process of elimination, not in the process
of absorption. It is not without interest to recall that if
certain individuals get fat on white bread it is because this
bread is poor in magnesium due to a sifting procedure which is
much too gross, all the "rich" part of the grain having been
eliminated to be resold separately at very high prices. But
few simple formulae have survived in dietetics, alas.

And, likewise, how many simple formulae have
survived with physiologists? For the majority of them --- and
the guilty are teachers, for the most part, particularly
chemists --- a carbohydrate is a tertiary composition where
the hydrogen, oxygen and carbon are clearly defied
constituents. For example, for decades they have accepted
without reservation that pure saccharose was always
saccharose, that there was one possible formula, confirmed by
all methods of chemical analysis. Accordingly, its biochemical
properties are always the same. But this is not true and if
the chemical formula remains clearly the same, nevertheless
its biological properties differ in accordance with the origin
of these saccharose substances. Thus we can distinguish a
saccharose from a beet, which does not have the same isotopic
composition as can sugar. Nature makes use of several methods
to separate isotopes, to modify the isotopic composition, and
in critical proportions, making a lie out of the simplistic
conviction of too many physicists for whom the isotopic
composition of an element is obviously constant. In the
bibliography at the end of this publication one may refer to
the works of Bricout referring to various authors. We see that
it is now a common practice for the Service des Fraudes and
customs office to use mass spectrometry to reveal if a
saccharose comes from beets or sugar cane, because the import
quotas differ as do the prices.

The confusion has persisted for a long time
because, still too often, classic instruction only takes into
account the Calvin cycle in considering the function of
chlorophyll. But this is the cycle utilized by the beet and
most dicots and too many publications still ignore the cycle
of Hatch and Slack, used in photosynthesis of sugar cane and
the majority of monocots. They have understood better that by
adding tap water to dried fruit or to concentrated fruit juice
one cannot obtain the qualities of fresh fruit and fresh
juice. The water in a fresh fruit is not the water found in
rain, in an irrigation ditch, or drawn from the soil; it is a
different compound at the subatomic, neutronic level. The
number of  neutrons differs as a function of the origin
of water but the number of protons and, accordingly the number
of electrons remains the same and it is therefore impossible
for chemistry to differentiate them. I will return to this
later on because it has various implications which many
chemists, atomic physicists, agriculturalists and
nutritionists have not taken into consideration. This
situation will be considered more carefully with respect to
the functioning of chlorophyll, a mechanism which is
fundamental to this differentiation in isotopic behavior.
However, I will not undertake a detailed study of that because
the isotopic separation provoked by the metabolism of the
plant is not a transmutation. In a way it is a kinematic
operation between heavy and lighter isotopes. Heavy hydrogen,
or deuterium, is approximately twice as heavy as ordinary
hydrogen which has no neutron as opposed to one neutron in
deuterium. The speed of the reactions has a substantial effect
and Ponticorvo, in a thesis written in 1958, cited by Bricout
(cf. reference section) calls attention to a reaction which
leads to a 70% diminution of deuterium which, from all
evidence, is very significant and cannot go unnoticed in a
spectrometer.

This property of living matter is often not
taken into consideration by physicists who undertake analyses
with an a priori assumption of isotopic constancy or, on the
other hand, by biologists who use radioactive tracers and
generalize conclusions from data which are only observed under
very limited circumstances. A more precise study is definitely
called for, particularly in view of the fact that a
radioactive isotope destroys cellules and thus opens a pathway
which modifies the behavior of a stable isotope. I dont mean
to say that we should abandon using radioactive tracers, but
we would be well advised to be cautious in making judgments
based on their repeated use. Belief in constancy of isotopic
composition is an idea too easily adopted without a critical
attitude and it sometimes leads to errors.

**(2) Lavoisiers Law ~**

The preceding comments show why it is wise to be
cautious about general application of Lavoisiers laws in
biology. In no way do I reject these chemical laws, but let us
leave them in their place. The statement that "Nothing is
lost, nothing is created" actually is just a play on words
creating a certain impression, Reality is more complex.
Chemistry is indispensable in order to understand molecular
transformations, which were the only sort of transformation
which could be demonstrated in Lavoisiers time; but at the
atomic level they become inadequate even for those who take
the position that in living matter there is nothing but
chemistry, since phenomena occur there which can only be
studied in terms of physics; electrical effects, pressure,
heat, movements, etc. This is true even if one takes the
position that chemistry is simply a branch of physics and is
explained in terms of displacement of electrons. The present
study will show that living matter employs energies which are
not electromagnetic, that nature also operates right into the
heart of the atomic nucleus, which has nothing to do with
Lavoisiers laws. Lavoisier was completely ignorant of this
aspect of living matter, even though his contemporary, the
great French scholar Vauquelin, suspected it. However, he was
a century in advance of physics and had no practical way to
study the phenomenon.

Even in our time there still exist
pseudo-scientists (by profession) who take the position: I do
not doubt your analyses, but if you no longer find an element,
that is because it has gone off somewhere else where you have
not searched for it. Because, for them, nothing is lost..
certainly, I could not analyze out an entire human body at one
fell swoop. Studies made on calves were subject to the same
criticism: the analyses could not have been carried out on the
entire calf. And so I worked on lobsters, but in this case the
reproof was that I had only used 8 animals. I carried out my
studies on 48 mice and for various reasons the animals were
totally dissolved in acid. This is a complex operation because
one risks the formation of soaps, by saponification of fats;
there are difficulties in dissolution of the keratin of the
hair, etc. I have described these various experiment sin
previous publications. The complexity of the procedures gave
too much opportunity for criticism for there is nobody more
deaf than he who does not wish to hear. And so I decided to
proceed only with relatively simple operations, working only
on plants and finally limiting myself to the study of
variation of one single element, calcium, in a single plant
species, oats, under hydroponic culture, without involvement
of a complex culture medium, using only synthetic water
(hydrogen and oxygen) or double distilled water. Water
demineralized on ion exchangers was not always sufficiently
pure. Or it might be necessary to distill permuted water.

In this process I found myself in cooperation
with Zundel and his studies will be cited further along.

Working with tens of thousands of seeds I could
now talk only in statistical terms, in terms of averages,
where any individual difference between seeds more or less
vigorously disappeared before the law of large numbers. These
analyses, applying to hundreds of cases, lead to proof that
one finds, in a calcifugous plant, a great deal more calcium
in the plant than there is in the seed from which it came. By
incomprehensible quibbling certain chemists have extracted
from this only a proof that they were incapable of making a
good analysis. For them the discrepancies in calcium
composition derived from the fact that in the seed there were
undetectable "hidden forms" which became identifiable after
germination, after mineralization by oxidation. Now the
"organic" form in the seed could not be discovered by
titration. Whence, evidently, an augmentation of Ca in the
plant. Now other chemists equally incompetent, equally
dogmatic, explained the contrary, taking the position that in
germination insoluble forms were produced, which could not be
measured by titration, and that most "seriously" of all. What
a pity for their students.

Now variations have been discovered not only
with respect to augmentations. For certain elements in a plant
species, in extra pure water, with acid pH, there can be
reductions. I will take the opportunity to deal precisely with
these aspects of analytic methods.

Certain people suggested to me that I call this
book my Testament", considering my present age. But, in
science, I take the position that there is no such thing as a
"last will". I would be presumptuous of me to think for one
instant that anybodys scientific contribution can be regarded
as advice to be followed in the future. Science itself is in
full charge. In no way can we anticipate when the results of
scientific progress will be replaced, when we will have
attained the asymptote of the curve of intellectual growth.
Thats why, when in 1979 I thought to write the present
publication, I could have entitled it "Twenty Years Later", a
title which would scarcely relate to me! It would more
appropriately be my "swan song".

More modestly, then, you will find in the
following pages a tally of more than 20 years of work done by
different researchers who became interested in my first
publications showing that there were in the metabolism of
living matter, both animal and vegetable, some aberrant
phenomena which could not be explained simply in chemical
terms. Only through nuclear physics could we come to
understand such findings resulting from irrefutable
investigations and I used to advance the statement: there are,
in that which lives, certain transmutations, which, to
abbreviate and to avoid confusion, I called "biological
transmutations", avoiding use of such expressions as fusion
and fission, which called to mind atomic bombs, since we were
certainly concerned here with a phenomenon of nuclear physics
totally different from high energy interactions, which are the
only ones which the majority of classical physicists were
studying.

I explained this in my first article, which
appeared in 1960, and even more fully in my first book, *Biological
Transmutations*, which was issued by Maloine in Paris
(1962). This publication at the end of the same year, was
translated and published in Japan, at the instigation of G.
Ohsawa, then some ten other publications followed in France
and abroad with so many reprintings that, in 1980, somewhat
more than 100,000 copies had been issued. The "biological
transmutations" had, accordingly, made their mark despite
certain oppositions which are inevitable when one upsets
accepted ideas, taught traditionally, sacrosanct, and
distributed via all channels: books, reviews, television,
radio, where certain people had established their position
such that they could no longer recognize their error, which is
not scientific. But I received numerous positive supports from
eminent scientists, without loss of professional position,
above and beyond dogmatism, who determined that my studies
were unimpeachable, and I was able to accomplish numerous
publications, conferences, etc., in France and abroad in order
to subject my material to discussion. For we had recognized
and accepted data. It remained to explain the phenomenon; and
any explanation is more or less subjective and dependent upon
knowledge which is more or less accepted at the time.

In any case, after 20 years, Science has
evolved. Thats why the present publication seemed to me to be
necessary. I do not intend to disavow my first publications,
but rather to clarify, to abstract certain prospective notions
which have not been realized, which will not arrive, perhaps,
until later on. It is also intended to set aside certain
over-extended representations destined to concretize a
phenomenon produced in our cell structure at an imperceptible
level. To explain is to attempt to force facts into the
framework of theories which the majority of scientists accept
at a particular time. But these theories have evolved in 20
years. Accordingly there are representations to be
reconsidered and it is not excluded that we may definitely
throw out some comparisons which I made about 1960 and shortly
thereafter. I will show as an example that very recent studies
recall certain representations which I proposed some time ago.

Certainly, the facts and the experiments remain
and retain their value for all time, except for experimental
error which was not detectable at the time. It is the
explanation of these facts which has evolved.

That led me not to follow through on certain
reprintings. For, in 1974, a sharp turning point in
theoretical nuclear physics led me to rethink the entire
theoretical portion of my studies and that will be seen in
greater detail in the second section. For this reason I ask
the readers of the present publication to disregard
explanations of my books in review articles or sound
recordings, etc., prior to 1974. In a sense, they no longer
have anything but historic interest. But I do not totally
discard certain analogies which can be useful and are not all
absolutely false. Certain recent advances in exploration of
the atom show that some notions that I expressed in the early
1960s seem to be confirmed but cannot be generalized in a
simplistic manner. This infinitely small world escapes out
senses in a way which renders it unwise to bend it into a set
of images structured for our senses on a multi-molecular
scale. Only my book *Preuves en Biologie de Transmutations
a Faible Energie* (first edition 1975) will be reprinted.
That publication contains a general perspective of the
principal experiments which enabled me to conclude that there
are effective transmutations of elements by biological
mechanisms and what are the extensive applications that they
have found in medicine, in agriculture, and in dietetics. The
present work scarcely touches on applications, constantly
changing, and attempts primarily to make available to
scientists the irrefutable indications showing that such
transmutations do certainly exist and that we now have an
explanation in theoretical physics which permits their
accommodation in classical studies. Therefore this is a
complement to the 1975 publication which will be kept up to
date in future printings.

I wanted the present book to adapt to meet the
most up-to-date theories of nuclear physics and also to be an
inventory of various researches specially undertaken and
irrefutable in terms of scientific method. I wish to set forth
certain material involving details which must be carefully
considered because experience has shown me that well-known
specialists were not capable of obtaining transmutations
placed within the framework of theories which were unfamiliar
to them. Due to some sort of professional defiance or to
ignorance resulting from over-specialization, but in any case,
unfortunately, most difficult to get rid of, they cannot see
the decisive role of this or that biological situation.
Routinely they are led into errors because they wish to
transpose the concepts they hold to a new science which
demands that they set up certain practices and theories which
are completely out of line with those that they have always
employed.

Not everyone can set aside the concepts into
which they have been formed (or deformed) ever since their
earliest schooling. I will sow a few examples, but it is
obviously impossible to address every aspect of this new
problem which leads to calling in question an array of notions
which are regarded as classic. One must reflect shift ones
wisdom, avoid automatic reaction. For all of us, when we do
not understand we must wait for the moment when we will
understand.

The problem studied here remains in conformity
with known laws of physics. The reason that we have studied
transmutations for the most part among biological channels for
the past 20 years is because this milieu gives a relatively
easy means of producing them and then reproducing them. And
this is accomplished under very precise conditions which
preclude generalizing in a naive and infantile manner. The
energy action which precipitates the transmutation demands a
combination of certain specific conditions; it does not appear
in a seed kept dry but does show up after a few days in a seed
placed in a condition permitting germination. There is then
produced a synthesis of enzymes which modify the spatial
structure, the stereochemistry of certain proteins
constituting ADN, ATP, etc. But this structural modification
is just a preliminary stage. It leads to exponential
multiplication of the capture cross-section (effective capture
cross section) of molecules with cosmic neutrinos in this
ocean of particles in which we bathe.

We are not dealing here with some mysterious
property which calls in some sort of vital principle more or
less well formulated from another point of view. I have, in
fact, been able to show that certain minerals, in combinations
in metamorphic rocks, so-called because experimentation and
observation have shown that they can change their form: these
minerals can show transmutations in line with the same
theories --- however, on a different scale, because
stereochemical modifications which occurred with the
application of temperature and pressure which "fluidifies" the
mineral makes atom displacement easier and these rocks, having
come under the influence of cosmic neutrinos, modify their
atomic composition both qualitatively and quantitatively. In
my 1975 book I dealt with research done under a pressure of 50
kilobars and a temperature at the 850 deg C level. And so we also
have applications in the study of mineralogy and I will come
back to that briefly, from another point of view, because
eminent geologists have been able to advance explanations of
phenomena which were completely incomprehensible in terms of
classical theories.

---

**Chapter 2**

**Experiments Establishing With
Certainty Certain Biological Transmutations**

**(1) Condensed History ~**

I refer the reader, for more details, to my
basic book of 1975: Proof in Biology of Weak Energy
Transmutations (Maloine, Paris). None of my prior publications
will be printed again in full.

In the title of this book I did not retain the
expression "biological transmutations" and replaced it, as in
other publications, after 1963, by the more general expression
"weak energy transmutations" because I was fully convinced,
since my first publications, that this phenomenon demonstrated
by numerous experiments was more general than simply
biological and I referred to it in my second publication of
1963 by the term "Natural Transmutations". In the present
volume, in order that one not lose sight of this general
aspect, I have summarized in one chapter a few applications in
geology, but it is a very limited presentation of several
studies appearing since 1975. However, it is not my intention
to take applications into account here, and it would be good
to have a book expressly aimed at studying the impact of weak
energy physics specifically on mineralogy to get a view of
everything available in this domain. I will refer to several
publications, one of which has more than 90 tightly written
large pages, and there are some publications which have
appeared abroad. It would certainly be desirable to distribute
a synthesis of the essential experimental studies along these
lines because one must have very costly materials for this
sort of investigation while in biology any laboratory can do
research without great cost.

However, here I wish to convince people that
transmutations of elements can take place with low energy in
living matter under conditions which will be made precise for
one must never say that a phenomenon is general, that it
occurs everywhere all the time. What I wish to show is that my
researches are a consequence of putting to work weak energy
interactions, and not a consequence of high energy
interactions which have been the only sort of interactions
that most physicists have considered since 1974. I save the
study of physics for the second part. This is fundamental
because too many scientists have their minds twisted by
physicists subjugated by the atomic bomb which led too many of
them for some 30 years (a whole generation unfortunately
prolonged in distortion by those who continued teaching) to
deny the existence of and fail to see the possibility of weak
energy transmutations. However, the majority of truly great
physicists did not lose sight of natural weak energy
transmutations, and I will come back to that, but these weak
energy transmutations are a phenomenon which is no less
striking than atomic explosions and the contribution of these
truly great physicists was more modest than that of the
majority.

When I discovered these biological
transmutations and decided to publish my conclusions, I was
not thinking of integrating these findings with what was known
(actually very little) concerning weak energy interactions.
More to the point, I did not know that very early experiments,
conducted over a century and a half, had demonstrated the
creation of certain elements and the disappearance of other
elements (or, more precisely, the augmentation of some and
diminution of others). Biological observations in animals and
plants were numerous and varied, but for very "humane" reasons
they had been kept under the blanket and were relegated to
trivial publications which people were reluctant to quote and
therefore they remained practically unnoticed.

But millions of people, via my publications,
widely disseminated reviews, by radio and by television (and
because my official functions made silence impossible) learned
about my studies and among them were those who were aware of
previous experiments and several called these previous
experiments to my attention. I should recall, for example,
that the major popular science review *Science et Vie* (*Science
and Life*) devoted several articles to this from 1960 to
1963 in some 350,000 copies. Europe No. 1 (June 1961)
distributed my 40-minute interview with Jacques Mousseau and,
previously, the Belgian television 819 devoted about a quarter
of an hour to these matters in December 1960.

If the above mentioned publications remained in
the dark for the most part it was because they were premature
in the sense that they were incomprehensible and too many
people deny that which is not understood even though the facts
are indisputable. However, I advanced an explanation by a
mechanism which had nothing in it which was mysterious for the
20th century because it was in some ways parallel to fusions
and fissions of the new atomic physics born with the century.

Lacking an accepted scientific explanation these
publications were often rejected out of hand on the ground
that they resulted from experimental error. Furthermore, it
was impossible because it would be a return to alchemy. That
had been definitively thrown out by science of the 19th
century. One could no longer go backwards. It was absolutely
necessary, however, to proceed to the evidence of the turn of
the 20th century.

The discovery of radioactivity demonstrated in a
striking manner that transmutation of elements was impossible
to deny. One could study it better when, in 1919, the first
forced transmutation was achieved while in 1935, there was a
successful artificial production of new radioactive
substances.

In 1963, the atomic physics professor of the
Conservatoire National des Arts et Metiers made available to
me photocopies of several dozens of pages in which Freundler,
a Sorbonne professor, condensed, in a 1928 book, studies
conducted for more than 10 years on the production of iodine
by algae. He is the first, to my knowledge, who saw that there
was a connection between the tin of the granite support and
the iodine in these plants. He had sensed the type of reaction
that I indicated but he had not been able to convince anyone
of this. He had come too soon and his calculations had a weak
point. The balance of charges and masses was defective because
the neutron was unknown at that time, not having been
discovered until 1932. But nobody else, even after 1932,
dreamed of reconsidering the problem which was nevertheless
cross-checked, as it were, by converging studies. I touched on
the work of Freundler to a certain extent in my book of 1963
on natural transmutations, which, after two editions, was not
printed again.

Readers of books failed to see a good many lines
which were rediscovered and took on new dimensions when those
readers saw my first publications. It was in just this way
that a friend of mine called my attention to a passage of
Flaubert in Bouvard et Pecuchet, a publication which
challenged the science of the 1880 era in a series of critical
dialogs. One chapter was written by Flaubert under the
inspiration of Regnault, a physicist well known to schoolboys
because of his Thermodynamic Tables, specific heat, etc., and
by Giraudin, an agronomist of world-wide reputation. Flaubert
emphasized that the great French chemist Vauquelin (a
contemporary of Lavoisier but more open-minded than the
latter) had demonstrated that a chicken fed exclusively on
oats laid in its eggs and in its droppings more than four
times as much "lime" as it had ingested with the oats which
had been analyzed beforehand. He provided a balance sheet for
the "lime", which was what we would today call calcium
carbonate, and also that for "lime phosphate" because the
balance sheet for phosphorus was also modified. But the
spectacular finding was the augmentation of calcium. There
was, according to Vauquelin, a creation of matter. His memoire
had been published 19 January 1799. He tried to see what could
have been reduced in order to give all this "lime". But in
those times people did not know about the atom and he did not
conceive of certain possible origins. I was able to obtain the
original of this remarkable piece of work and discovered that
they knew very well how to make precise analyses of calcium at
that time. But Vauquelin knew how to isolate and discover
certain "simple substances" and he was a very talented and
clever experimenter. Furthermore, in those days it was the
main boss himself who made the analyses and not a laboratory
assistant. In my 1975 book I devoted 10 pages to presenting
this remarkable study which, in my opinion, constituted the
oldest and one of the most serious experiments before the
atomic era on biological transmutations, an expression which
had not yet been formulated in the 19ht century and was much
less available in the 18th century. I did not mention this
test in my first publication because I did not discover it
until about 10 years later.

That indicates that Lavoisier had produced an
absolute law which was true within the framework of chemistry
but in chemistry only. Vauquelin showed that there was
something else in living matter and that the problem is more
complex than in the chemistry of non-living material. This
shows the great historical importance of this 1799
publication.

I also refer to my 1975 book for the very
important studies published from 1875 to 1883 in Germany by
Von Herzeele. He did numerous experiments on a great many
species of seed germinated in a dust-free situation with
distilled water containing a mixture of two salts. One of the
salts always contained a constant anion and a cation which
varied with each experiment. In other experiments this was
reversed: constant cation, variable anion. We see that this
investigator anticipated the phenomenon of transmutation and
was studying the correlation between the augmentation of one
element and the diminution of another. But at that time atomic
structures were not known. He was then about 20 years before
his time. However, the results that he obtained are very
important since, after Vaquelin, we have a second stage,
conducted scientifically, a valuable example of researches on
variations of certain elements as a function of metabolism in
the germination and growth of various plants. Certainly, Von
Herzeele (and several others before him, not knowing the
structure of atoms, completed certain experiments which had no
significance, but some of his experiments are valid. In
addition, being a chemist, that certain reactions are only
possible as a function of the pH of the culture medium and
could not be conducted except in line with the needs of plants
which could be either calcifugous or calcium dependent. In the
same way nitrogen needs are not the same for legumes as they
are for grasses, etc. The chemist did not see certain aspects
of plant biology. This was also the case 80 years later for P.
Baranger, who was head of the laboratory of organic chemistry
at the Ecole Polytechnique de Paris and did not see certain
aspects of physical chemistry such as the importance of
photosynthesis and its relation to the incident light spectrum
and the materials through which the light passed. He was a
doctor of sciences and had done a thesis in chemistry.

**[FIGURE 1](fig1.gif)
~ Photocopy of Nobel Prize nomination**

**[FIGURE 2](fig2.gif)
~ Photocopy of Nobel Prize nomination, cont'd.**

---

**Chapter 3**

**Several Examples Of Experiments
Subsequent To 1974**

I will limit this chapter to just those
experiments done on oats, referring to my book of 1975 for
various experiments on humans, animals (such as mice,
lobsters, etc), or with microorganisms, I will briefly
comment, in passing, on various results published here and
there concerning carbon, silicon, phosphorus, manganese,
copper, etc., as they relate to plants. I will not attempt to
present in detail various complementary experiments on oats or
other plants to study variations of elements such as sodium,
magnesium, silicon, copper, etc.

However, I would like to call attention to the
fact that studies on the variation of copper in cultures of
oats (a plant which is, in the overall, rich in copper) have
showed that, with respect to the seed, the plant shows a
reduction in the neighborhood of 19% (mean figure from the
analysis of five batches). But I judge that we did not have a
sufficient number of batches studied to generate a meaningful
hypothesis concerning what it is that increases when Cu
diminishes (possibly zinc?). My researches on the Mn-Fe link
are also not extensive enough although the results tend to
converge; however, we must look more closely at reactions in
this domain.

I will present in some detail an array of
experiments bearing at one and the same time on potassium and
calcium in oats in order to show the principal precautions one
must take when one comes with naive eyes into a research area
that others have seen from a very different angle. Then I will
give in another chapter a few results of research accomplished
by J.E. Zundel, research carried out subsequently to those
cited in my book of 1975, which he expanded considerably later
on and which he carried out limiting himself almost
exclusively to variation of calcium in hydroponic culture of
oats, in order to show the scope of detailed parameters one
must lose sight of in this sort of research. As he always kept
me current with his results, I will set forth the core of his
research, more especially the memoir that he circulated in the
1979 second semester as a photocopy --- then in an Italian
university review in 1980 --- under his signature and
consisting of an excellent condensation of 13 years of
practically uninterrupted research. Thanks to this huge amount
of work focused on a precise area I believe that the study of
oat culture has been pushed to a point that we may be certain
there is an augmentation of Ca in the order of 100% (varying
from 50% to 150% as a function of oat variety, season, etc.),
the increase occurring in a plant which has germinated several
weeks being compared to a grain similar to the one from which
it came without there being any chance that this calcium came
from the air, the water, the materials used in the culture
equipment, or as an artifact of analysis. Unfortunately, due
to human vanity, I understand that it is very difficult to
obtain exact replication of an experiment. There are many who
consider themselves superior to the rest of the world (or more
clever), and they criticize what has been accomplished, desire
to generate an experiment modifying the results in line with
their own procedures or materials in order to get their own
name in the ring. Thats human. But also quite frequently that
comes from a misunderstanding of the main problem resulting
from distorted professional judgment.

But these inevitable human eccentricities did
not curtail widespread dissemination of what some call a
"mutation" and what I call a transmutation, a label adopted
universally for this physical phenomenon of the mutation of
nucleons in atomic nuclei. Thus it is that Prof. Genevois, in
the introduction to his Biochemical Mutations of Plants, was
able to write a few years ago, "It now seems, from collecting
the facts on all cultivated plants of any importance, that the
condition of mutation is a general fact. Mutations are in the
process of changing domesticated vegetation. Perfecting
analytic techniques... that consistency of the composition of
plant species was an illusion". One could not say it more
clearly, but it is so pleasant to cradle oneself with
illusions, right up to ones death!

Now lets demonstrate scientifically that
consistency of structure is truly an illusion to be dispensed
with!

**(a) Research on Variations of Calcium and
Potassium in Culture of Oats ~**

I elected to continue investigating oats because
that is the most calcifugous cereal I have every encountered
in my studies. It grows well in acid soils (granites, for
example). Accordingly, one can grow it in a laboratory with
extra-pure water which is almost always acid (therefore a
proton donor according to the modern definition of the acid
state --- and we must not forget that which represent the pH
of a pH meter). Accordingly one must avoid neutralizing or
"stoppering" it. I used extra-pure water resulting from
combustion of hydrogen and oxygen, these two gases being the
product of electrolysis. They were, then rigorously pure,
which is not always the case when, for example, hydrogen comes
from a reaction of sulfuric acid on zinc. The zinc is often
too impure except when it has been produced by electrolysis.
Commercial sulfuric acid is often produced by calcinations of
a very complex mixture of pyrites which requires that it be
rejected for experimental use unless it is a pure acid coming
from refined sulfur. It was not always possible for me to have
a sufficient amount of such water; then I used bidistilled
water because in water which has been distilled only once a
"head" [azeotrope] is formed at the outset of distillation, a
condition in which there are very diverse volatile products
which condense before anything else --- organic products which
are often toxic. My colleague in the Paris Council of Hygiene,
P. Levine, of the Pasteur Institute, advised us that he was
not able to conduct certain experiments in microbiology or in
human biology using the water of Paris with just one
distillation. He found it necessary to throw out the "alembic
heads" and redistill the remaining condensed portion.

Softened water, purified on ion exchange resins,
also called permuted water, still contain too many minerals
for our research work. Permuted as well as possible, they must
still be distilled by a single passage. Analyses of every
batch of water were made by atomic absorption
spectrophotometry on samples which varied from one to three
liters per carboy and were reduced to 50 ml by evaporation to
ensure they did not contain a measurable amount of Ca++ and K+
(since the experiments were concerned with these cations)
which could have influenced the results obtained by more than
one percent. Such experiments were also carried out on all
those materials which might come in contact with the cultured
plants (purex, plexiglass, altuglass, polyethylene, etc.). It
was also necessary to consider analyses at different stages of
the operation to be on the lookout to avoid having parasites
get into the circuit.

It seemed to me advisable to cite a few examples
of such experiments, according to publications that I
distributed in photocopies, for the most part, extracting,
however, all the material which was simply repetitious.

**(b) Research on K and Ca in Oats ~**

I abandoned research on calcitropic plants, like
ray-grass, due to a lack of time and personnel, and in the end
I limited myself to studies of oats, a calcifugous type of
plant. In these efforts I made use of the publications of
Zundel and some others. Thus, I could take into consideration
a very large number of results showing a statistical
convergence which could not be denied by any conscientious
person. And very shortly thereafter we find balance sheets on
Mg and Si which, under certain circumstances (in animals for
instance), both may be able to transform into calcium. Already
in 1799 Vauquelin had demonstrated that if silicate diminishes
and lime increases when one tallies up the content with
respect to a chicken as a function of ingested oats, the
diminution of Si does not correspond quantitatively to the
augmentation of Ca. Some studies --- perhaps too few --- have
shown that in the germination of oats Mg and Si did not play a
significant role in the production of Ca. By contrast there
were a good many experiments confirming that there was a
diminution of K commensurate with the increase of Ca.

Zundel, likewise, only carried out a few studies
on Mg and SI in his oat cultures because his first
investigations showed him that the variation of these two
elements was too slight and insignificant with respect to the
increase of Ca. And he also set aside investigation of K for
two reasons:

He did not himself analyze K and did not wish to
simply play the role of confirmatory of that which had been
done by others;

It seemed to him that the various analyses which
he has had done by flame spectrometry, by neutron activation,
and by x-rays, for example, varied too much as a function of
the methods, the operators, the laboratories, and even the
operators in one laboratory using the same method. Repetition
was not assured with respect to the numerical values of K that
were given to him and he had no way, himself, to determine the
results which he could trust because he placed his confidence
in gravimetric chemical analysis, weighing milligrams of
cations. In this way he could measure to one-tenth of a
milligram the creation of Ca, but with respect to what? He
does not pass judgment on that.

I will not give here results obtained by
chemical methods, gravimetric or colorimetric. Rapid analyses
for crude verification have been made by various methods of
complexometry (by EDTA for example). They are often more
delicate to accomplish than one might think because the
complexant must be chosen as a function of the affinity
between Mg and Ca. I indicated in my book of 1975, with
respect to research on the lobster, why it was necessary to
reject certain methods because the affinity of Mg/Ca varied a
great deal as a function of the metabolism of the animal.
After moult of the lobster, the method did not work in the
majority of experiments which made it very difficult to obtain
results which could be properly compared.

**[ PARAGRAPH MISSING ]**

I know --- and I have cited some results ---
that convergent values for Ca have sometimes have obtained by
flame spectrometry. But I cannot have confidence in them a
priori; they must be cross-checked, because some equipment
uses a flame of a temperature insufficient to ionize enough Ca
atoms and obtain valid and reproducible results. It is also
preferable to have the same operator in order to better
control the regulation of the flame (the delivery and pressure
of the gas must be verified regularly).

**(2) Simultaneous Investigation of Mg, K and
Ca ~**

To avoid a long drawn out description in the
following paragraphs, I will present only mean data for each
whole experiment and will not give mean data for each
experimental segment. Obviously, in this experiment it serves
no purpose to take account of variation in Mg since that
result has been obtained from ten other experiments conducted
to obtain balance sheets of Mg when placed in a culture of
oats of different varieties. Thats one reason which led me to
terminate research on variations of Mg in 1976.

Comments on Analyses of K, Ca and Mg in Seeds
and Plants of Oats in the Paper-Mill Analytic Laboratory of
the Grenoble University Complex ~

**(a) Experimental Protocol ~**

Oat seeds of the Flamingskrone variety (a blonde
hybrid) with a 27,5 mg mean weight per seed were germinated in
special vats covered with an indented plate with two seeds per
indentation. The vats received double distilled water with a
pH = 5.6.

A preliminary control was accomplished by
destroying the water and material of a vat to accomplish
spectrophotometry of atomic absorption to verify that there
was no measurable amount of calcium therein. The culture was
accomplished without added fertilization.

Germination took place in an enclosed space of
about 70 x 40 x 30 cm of transparent plastic material out of
contact with seeds and water. The enclosure was swept with air
sent by an electric pump at a rate of about one liter/minute.
This air passed through an air filter provided with one meter
of hydrophilic cotton folded and compressed. Then it was
muddled through four one-liter glass bottles, each filled with
750 ml of double distilled water, arranged in a series. The
first was supplied with 30 ml of HCl to precipitate any trace
of calcium dust which might have passed the filter. Then the
air passed successively through two bottles with additives of
NaHCO3 in order to neutralize any trace of acid drawn by the
air from the preceding bottle. The fourth bottle contained
only pure water.

Thus, neither by air, nor by water, nor by
material in contact with the germinating seeds was there any
possibility of an introduction of Ca into the enclosure where
there was an overpressure of approximately 3 mm water which
made it impossible for any entry of ambient air contaminated
by Ca.

At the end of several weeks the plants developed
from these seeds were gathered, dried, incinerated at 950 C,
dissolved in hydrochloric acid and aliquot parts were analyzed
by a number of methods in order to cross check results.

At the same time there were analyzed some
control segments of non-germinated seeds as nearly identical
as possible to those which were germinated. All seeds utilized
were calibrated and came from selected seedings furnished by
the INRA and their germination rate was better than 95%.
Nevertheless, each seed was hand-picked, the same for the
control segments as for those which were germinated, in order
to eliminate any abnormality of dimension (either too large or
too small) or presenting a visible defect of form or of color,
to have experimental segments as homogenous and as similar as
possible.

The essential purpose of the experiment, within
the framework of verifying my studies, was to compare the
quantity of Ca between seeds and plants in order to establish
a balance sheet showing that germination of the oat --- a
calcifugous plant --- in water with an acid pH will actually
alter the quantity of Ca a few weeks of growth in a calcium
free environment.

**[MISSING TEXT]**

...It was requested of the Paper-Mill Laboratory
located in the University of Grenoble complex (we note that
the University of Grenoble supports the Superior School of
Paper Manufacturing which trains the production engineers in
this profession) to measure not only Ca and Mg by
spectrophotometric atomic absorption but also to measure K by
flame spectrophotometry. This was to cross check the results
of previous experiments made by Kervran and by Zundel,
independently, showing that the increase of Ca discovered in
such experiments on oats would only have come from a reduction
of K which was quantitatively almost the same.

The measure of Mg was requested of Grenoble
because previous chemical analyses of Zundel and physical
analyses made by myself had always shown that in the growth of
oats, a calcifugous plant, the Mg was practically invariant.
One more confirmation of this came to light. I cite results
from this Paper-Mill factory done for Zundel who sent them
tome for my information. The analyses were accomplished in
1970-1971 but I did not publish my comments except by
individual letters in September 1976, with a photocopy of the
schedules of the analyses. The following is a combined study.

**(b) Tables of Results of Analyses ~**

We will only consider experimental segments with
identical numbers of seeds and plants, in the two studies, one
on Ca and Mg, done first, the other on K, done later, but on
aliquot sections coming from the same experiment.

**[TABLE
1ab](tab1ab.gif)**   
**[TABLE 1c](tab1c.gif)**

N.B. --- Question marks after a value indicate
that it is possible (in my opinion) that there was a slight
measurement error with respect to this sample.

**(c) Recapitulation ~**

The possibility of slight errors from one sample
to another is offset by the law of large numbers, the analyses
being carried out on hundreds of seeds and plants. The
following table recapitulates the above material rounded off
to three decimal places. Values are stated in mg

**[TABLE 2](tab2.gif)**

*Remark*: The variation of Mg in absolute
value is very slight ()0.0069 rounded to 0.007). The range of
values per plant, for the four analyses, runs from +0.0059 to
- 0.0072 whence, around the mean there is a dispersion of
0.0065 (also rounded to 0.007). That is to say, as a function
of experimental error, the variation is equal to the
dispersion. Fomr this fact we conclude that there is no
significant variation of Mg, which had already been confirmed
by a number of previously conducted experiments on oats.

**(d) Comparison of Variations in K and Ca ~**

In absolute value, K diminishes by 0.033 mg per
unit while in absolute value, Ca increased by 0.032 mg per
unit (between one seed and one plant derived from a similar
seed).

Thus there is a definite convergence between
these two values, which allows us to conclude that the
augmentation of Ca comes from reduction in K, from which we
have the following statement:

K 39/19 + H 1/1 >> Ca 40/20  + ~ 0.01
u.m.a.

In different experiments this compensatory
augmentation of Ca and reduction of K during germination of
oats in an acid culture has been observed to approximately +/-
4%, reflecting inevitable differences due to slight biological
variations and experimental errors. Again, we can present
these values as follows:

in a seed: K + Ca = 0.140 mg   
in a plant: K + Ca = 0.139 mg

Indicating that the total amount of K + Ca does
not change. or even:

in the seed: K/Ca  = 0.113 / 0.027 = 4.2
approximately;   
in the plant: K/Ca = 0.080 / 0.059 = 1.4  in excess,

which again reflects the reduction of K with
respect to Ca. As K + Ca does not change, the increase of Ca
can have no other origin than the diminution of K, which makes
it useless to look for some other origin of Ca. However, as we
find certain metabolic systems (especially animal systems) in
which Ca could come from Mg --- by the reaction Mg12 + O8
>> Ca20 --- due to complimentary adjustment, research on
variation of Mg was made one more time, in the experiment
commented on herewith, and it was discovered to be
non-existent. Likewise, other previous experiments had shown
that there was no significant variation of Si during the
germination of oats. Bear in mind that a calcitropic plant
does not manufacture Ca, which must be brought to it by the
culture medium.

The values of K and Ca, in both seeds and
plants, as set forth above, are accepted without reservation
because they confirm the mean measures supplied by other
investigators using a variety of different analytic
techniques.

It is noted that in this experiment the relative
increase of Ca is greater than 118%. The graph in Figure 3
clearly shows the reciprocal variations of K and Ca.

**(e) Review ~**

For purposes of comparison let us consider a
previous analysis by neutron activation made by a Swiss
government center for nuclear research on seeds of a closely
related variety, Peniarth (mean seed weight 32.2 mg). Analyses
were made on five samples of six seeds and five samples of six
pants each.

**[FIGURE 3](fig3.gif)**

**Figure 3 ~** Inverse variations of K and of
Ca in germination of an oat seed (Mg does not vary
significantly).   
Mean figures per seed, from 3 analyses and a total of 840
seeds.   
Mean figures per plant, from 4 analyses and a total of 403
plants.   
Analyses of K by flame spectrometry   
Analyses of Ca and Mg by atomic spectrophotometry absorption   
Analyses made at the Laboratory of Paper Products Analysis
(University of Grenoble).   
DK = 0.113 - 0.80 = -0.033 mg   
DCa = 0.059 - 0.027 = +0.032 mg

**[TABLE 3](tab3.gif)**

**Table 3:** Batches of 6 Seeds and of 6
Plants (Values in mg)

So again we have an augmentation of Ca in a
plant, compared with the Ca in a seed similar to the plants
seed of origin in the amount of 0.0560 - 0.0249 = 0.0311 which
gives an increase of 124%. We are not dealing here with the
same plant variety as in the preceding experiment, but we see
that the order of magnitude of variation remains very close to
the same. Actually, the values obtained in Switzerland were
corrected some time after issuance of the first analyses
because it was noted that, because of some germination failure
the values reported applied not to a total of 30 plants but
rather to an average of 28.32 plants, thus leading to a slight
increase in the amount of Ca calculated for the plants.
Another calculation was added, by comparing the content of Ca,
not just by the unit (seed or plat) but as a function of
weights and the values were given in ppm, which allows us to
compensate the inequalities of weights of the samples to
obtain a more homogenous result. This led to confirmation of a
138% increase of Ca.

We can briefly add other results showing the
convergence of values obtained by different laboratories,
always with oats:

1. Nuprime variety, Kervran culture, 42 days;
analysis by Dr Bieselaar, former lab director of Fraud Service
---- Atomic Adsorption Spectrometry; average grain weight
24.65 mg (dozens of experiments with this variety have given
average weights from 22 to 25 mg, according to the source of
the lots).

2. Flaningskrone variety; average seed weight:
27.5 mg (has varied from 25 to 30 mg according to the source.
Ca/seed: 0.028 ~ Ca/plant: 0.056 ~ Ca change: +0.028 = 100%

3. Peniarth variety: using neutron activation,
52 day culture; Ca/seed: 0.057 ~ Ca/plant: 0.052 ~ Ca change:
+0.0263 = 103%

4. Same variety, dosed by atomic adsorption
spectrometry, after 48 days of culture: Ca/seed: 0.0260 ~
Ca/plant: 0.064 ~ Ca change: +0.038 = 146%

5. Peniarth variety; using neutron activation,
Ca/seed: 0.0249 ~ Ca/plant: 0.0572 ~ Ca change: +0.0323 = 130%

**[FIGURE 4](fig4.gif)**

All these examples definitely show similar
results and an average increase in Ca greater than 100%, which
is absolutely beyond all possible experimental error and
confirms the "creation" of Ca, pointing to a transmutation. We
have seen that it begins with K. Dozens of experiments, made
up of hundreds of analyses, performed by different
laboratories using varied methods, have been conducted on tens
of thousands of oat seeds and plants. The phenomenon of
transmutation is therefore well established beyond doubt. The
increase of Ca tends to become asymptotic after 5 days too 6
weeks of culture, which implies an exhaustion of synthetic
hormones during germination.

A transmutation by a lining organism does not
follow the classical rules of high energy interaction. Instead
it can be classified in the category of low energy
interactions. The loss of mass is not explained by a release
of heat and is not represented by any radioactivity --- alpha,
beta, or gamma. In my 1975 book, Costa de Beauregard, Research
Director at CNRS, showed after the confirmation of "neutral
currents" in 1974 that the loss of mass is explained by
introducing the action of neutrinos. Therefore, the loss of
mass does respect the classical theory of physics. I have
added to it the action of the neutral intermediate virtual
boson vector z, and the previously stated reaction could be
written as:

C + K + H +Zo / + enzyme >> Ca
+ v1

with *v* prime not equal to *v*
pertaining to energy level. The introduction of the H+ proton
would be explained by the tunnel effect by application of
quantum mechanics.

In the above reaction *v* is different
from v from an energy point of view. The entry of the H+
proton would be performed by the tunnel effect in accordance
with quantum mechanics.

The text just quoted was released in French from
September to October 1976. It was soon after translated into
English and released in the USA by Dr E. Stanton S. Maxey,
surgeon and owner of a surgical-medical center in Stuart, FL,
who has done much for the release of my research.

The above stated results seemed to me definite
proof of an increase in Ca by an equal reduction in weight of
K. I saw, therefore, more or less, remarkable support to
establish the reaction proposed for approximately 15 years,
given by the formula K + H >> Ca, resulting from a great
number of observations which all tended to converge on the
same conclusion. I attributed the slight variations of the
numerical results to cultural protocol; to slight differences
in the strength of germination of the seeds; or to
non-eligible, hard-to-measure cosmic phenomena that have been
confirmed experimentally by numerous scientists, such as the
influence of seasonal changes, etc. Subsequent experiments
came to confirm such results.

**[FIGURE 5](fig5.gif)
~ Formation of calcium from potassium by the combined action
of an enzyme and a neutrino.**

The positive charges of the active site of the
enzyme repel the H+ proton. The result of this electrostatic
field is represented by H. H does not appear as a label in
this figure. [Ed. --- I think he means the result of this
electrostatic field is felt by H, as shown in the figure].

The enzyme would concentrate the neutrinos *v*,
increasing the chances of impact with the material.

A neutrino *v*, adding its effect to the
enzymes positive charges, repels the H+ proton towards the K
nucleus with sufficient energy for the proton to penetrate the
K by the tunnel effect. The K atom recoils a little from the
shock and becomes Ca (K19 + H1 >>
Ca20).

The incident neutrino *v*, which has
accompanied H, does not penetrate very far into K. It has
given up some energy to H and is refracted in K, leaving with
a different energy *v* prime not equal to v by carrying
off the excess energy resulting from the loss of mass between
Ca and K + H.

This re-emitted neutrino *v* prime will be
lost in space without reacting with the material.

But I have never been able to understand why
certain experiments performed elsewhere seemed to indicate
that there was not always a one-to-one correspondence in the
increase of Ca to the decrease in K, the loss of K being
insufficient to account for the increase of Ca. There was not
sufficient reduction of Mg or Si to compensate for the
increase of Ca. Nor did I see any evidence that the analytical
methods could be blamed. Was I to infer from this that it is
probable that we have not yet completely mastered the cultural
protocols that allow us to obtain reproducible results of the
K content?

But it was no longer possible for me, for
diverse reasons, such as age, health and financial means, to
start over again with a systematic study of the K life cycle,
which would take years. I therefore decided to continue only
with the research that always pointed to an increase in Ca,
since Zundel himself was not analyzing K, but was instead
specializing his research on the increase of Ca in oats. There
was a restricted but sufficient domain here to establish the
increase in calcium, and therefore the creation of matter in
the germination of oats. That is to say, there is a biological
process of transmutation of matter, and that there are other
phenomena besides chemistry in living things where there is no
evidence of high energy transmutation. But I thought for the
time being that we needed to be conservative about the role of
K in the formation of Ca. Researching the element, or elements
originating from Ca is quite another problem that young
scientists will have to solve in the future.

**FIGURE 6** **[Not included here]** ~
J.E. Zundels Research Station in Grasse, France (1976) ---
Environmental culture tanks. Pumps and purification flasks
that control the air sent into the tanks are in the back room.

First, I will present a study by Zundel that he
had published in September 1979. He only measured the calcium
content, as you can see the results in his summarized table,
which is reproduced also. Then I will go on to some
commentaries on diverse experiments, with the logical
conclusions that can be drawn from them. The following text
has been reproduced in French and Italian in *Rivista di
Biologia* (Fall 1980), Univ. of Perouse, directed by Prof
Sermont.

**(3) Research by J.E. Zundel ~**

I introduced this researcher in my book of 1975.
J.E. Zundel graduated from the Zurich Polytechnicum as a
chemical engineer. He then trained in the USA. He managed a
paper mill, keeping for himself the supervision of the
chemical analysis laboratory. This allowed him to maintain his
proficiency in the field of chemical analysis for the rest of
his life. He had a completely open mind and he was a deft
experimenter. My first works were a revelation to him. He
wrote to me as early as 1963. He understood immediately that
my works pointed to a whole new aspect of biology which was of
great interest for pulp and paper research or on all organic
material obtained from vegetable fibers. Some alterations in
paper could not be explained by chemistry alone.
Micro-organisms would implant themselves in the paper and
cause modifications which could not be understood. In 1963
Zundel began some preliminary verifications of my ideas after
broaching the subject with me in letters. His work was
intermittent, because his professional activities did not
leave him the tie required for continuous research. However,
this preliminary survey convinced him that my works contained
a reality, so far ignored by all chemistry treatises and
specialized periodicals. As soon as he retired, he moved to a
pollution-free location in the country, half way between Gasse
and Canes. At his own expense he installed a hydroponic
experimental station housed in a Vitrex greenhouse. Vitrex is
made of fine wire mesh dipped into pure Cellophane, a solution
of pure transparent celluslose. Vitrex is more permeable to
the solar spectrum than glass. It is well known that glass
filters some ultraviolet wavelengths. Vitrex is selective to
several infrared wavelengths which are conductive to the
greenhouse effect. This Vitrex greenhouse also protected the
plants against unavoidable small dust particles. Some dust was
still brought in and out of the greenhouse on shoes and
clothing despite these precautions. Zundel even worried about
dust carried by the wind from a quarry located 10 km away.
This was indeed improbable, but it had to be considered to
counter any subjective objections raised by the eternal
systemic objectors. To present accurate digital data, he
interspaced his planters with control planters filled with
pure water. In this way he could accurately measure eventual
dust fallout. In addition, he equipped a chemical analysis
laboratory for the measurement of Ca and some other elements
such as Mg and Si. He personally did the various analyses, as
he distrusted lab technicians (I appreciate these highly
qualified technicians. They are very useful collaborators.
Nevertheless, one should keep in mind the old saying: "Better
deal with God than with his saints", especially in a new
field, which has not been taught to them). This hobby kept
Zundel busy during his retirement.

It is important to note that Zundel never
measured K himself. This element is difficult to measure by
purely chemical methods. At Ecole Polytechnique in Paris,
Prof; Baranger. Director of the Organic Chemistry Laboratory,
also abandoned the various chemical methods prescribed in
classic analytical treatises after he had performed
questionable chemical analyses of the element K. Subsequently,
he used a physical method, fashionable at the time, in order
to avoid, as he told me, malicious comments by his "dear
colleagues", always ready to find faults in procedures set up
by others. Only their method is reliable. I will not describe
the multiple causes of uncertainty in chemical methods. They
are usually related to a sequence of the solutions ending up
with a compound which is insoluble in the next phase. Too many
chemists forget, in their quest for an element inside a seed,
that this element is related to different compounds in the
plant grown from this seed. They reason solely as chemists and
they forget --- or ignore --- biological phases. For a long
time now, analyses of K have been performed essentially by
flame spectrometry techniques (emission spectrometry) which
have been refined and automated. These techniques are easy to
set up with a butane or propane flame. However, preparatory
steps remain delicate for flame spectrometry as for other
physical methods.

When Zundel wanted values for K, he usually
would send ash samples to a well equipped Industrie du Papier
laboratory linked to the Ecole Superieure du Papier of the
University of Grenoble. In these cases, he only mentions the
results without lending them his support. He only claims as
his own the data which he obtained himself and checked by a
different method. This is the case for calcium which he
measures following a gravimetric method. The samples are
weighed on a high precision Sartorius scale sensitive to the
1/10 mg. This is sufficient considering the quantities
involved. Baranger weighed his sample on a Mettler scale
sensitive to 1/100 mg. Such precision is meaningless, because
it is subject to gravimetric variations such as the distance
to the operator. Most recent models were calibrated on very
heavy bases to minimize the influence of distance to the
operator. Still the operator should not get too close to the
scale and he should use proper remote controls. Protections
are necessary to shield the scale from the operators body
heat and breath.

Zundel performed tens of thousands of
experiments, including hundreds of analyses on tens of
thousands of seeds to establish a procedure guaranteeing
reproducibility. He wished then to check to results obtained
using the method recommended by Prof Charlot of Institut de
France in his now classic Traite dAnalyse in order to
eliminate any possibility of error. After preparing a sample
(an aliquot part) of ashes himself, he had it analyzed with an
atomic absorption spectrometer at Laboratorie des Industries
de la Papeterie in Grenoble. It was a Perkin-Elmer instrument.
I used a Beckman. He had the concentrations in Ca and also in
Mg, obtained by Charlots method, tested with this instrument.
We will not discuss these concentrations here, as the
variations in Mg proved to be small, if at all significant.
The results obtained by Zundel on oats regarding Mg confirmed
mine. I stated this point in my book of 1975. This is not the
case for the amount of the variations of Ca in oats, a
calcifuge plant. In calcicole plants the metabolism of Mg is
totally different. I will not elaborate on this subject and I
will limit my topic to a wealth of studies. In this field it
is not permissible to extrapolate results to other plant
species without having a very large number of data taking into
account the numerous parameters which should be considered in
the growing process.

Zundel used a third method, neutronic
activation, in order to check his data. He entrusted these
analyses to the Institut Federal de Recherches sur les
Reacteurs Atomiques located near Zurich. As Zundel could
cross-check the data by three totally different methods, he
was able to select the experiments which gave three sets of
compatible figures. Any large discrepancy in one of the
figures would lead one to suspect an error in the analysis by
the operator. In this way he happened to detect a dilution
error in an experiment with the atomic absorption
spectrometer. Ashes were dissolved in hydrochloric acid and
then diluted in twice distilled water prior to injection into
the instrument. The analyzer was programmed to average data,
measured automatically on ten samples contained in small test
tubes. In this analysis there were obvious variations in the
results as compared to those obtained in a large number of
previous analyses. The operator made the mistake by one order
of magnitude. Sometimes the error is due to an oversight. For
example, something sticks in the bottom of the crucible after
firing. A calibration error is another possible cause, so is a
zero displacement. These are some of the reasons why one
cannot rely on a single experiment.

I will mention again that I performed
germination experiments on two layers of ash-free filter paper
in Petri dishes. I measured the total Ca content of plants and
paper. In another experiment, seedlings were cultivated in the
cells of a seedling tray which had holes at their bottoms.
Operators had neglected to measure the Ca which migrated
through the roots to the underlying water. It was only an
error of secondary importance. I ascertained that this Ca
contained in the water (null at the start) represented
approximately 10% of the Ca increase in the plant as compared
to the Ca content of the seed from which it originated. This
increase was often greater than 100%. However, to be
rigorously scientific, it was necessary to take into account
the Ca content of the water. I informed Zundel of the
necessity to perform such measurements, which were omitted in
the first experiments.

In my book of 1975 I only mentioned Zundels
studies prior to1972, at which time he presented a paper to
the Academie dAgriculture de France. Zundel did not publish
from that time until 1979. He pursued his study continuously
during the whole period. I did not want to publish the results
he was sending me all along, in order that he would be the
first to do so. Also I only wanted to comment on data that he
had published himself so as to have a public database, which
would not be the subject of objections. I will reproduce below
a text printed in 1980 in the Rivista de Biologica (quarterly
issue, 3rd quarter 1980), published by the University of
Perugia. This is the original text followed by my short
commentary which is my sole responsibility.

**[FIGURE 7](fig7.gif)
~ Hydroponic Culture of Grains**

"The planter, presently made of polyethylene,
includes a tray in which twice distilled water is maintained
at a fairly constant level. The pH is 6.5. The water level is
topped off every 3 or 4 days to compensate for plant
transpiration. This is done by means of a fixed tube linked to
the outside by a siphon. The external extremity is covered
with a test tube as a hood for dust protection. The test tube
is only removed to introduce the pipette for water additions.
A multi-cell panel, also in polyethylene, is placed on top of
the tray. The 75 cells receive two seeds each. The roots reach
for water into the tray below, wile the seeds are maintained
outside the water (aerobiea). A maximum of 150 seedlings can
be grown in each planter. Two chambers, as the one reproduced
below, are fed in parallel from a same air supply.

"The planter is placed in a closed chamber made
of thick, rigid Plexiglass 70 x 40 x 30 cm. The box is closed
with a removable Plexiglass panel after introduction of the
planter. This panel is fixed by steel clips to one side of the
box. It is screwed to the box once everything is in place. A
gasket insures air-tightness between the panel and the box.

"Air is pumped into the chamber at an
approximate rate of 1 liter/minute by a device which is not
represented on the figure. The air is pushed through an air
filter by an electric positive-pressure pump. From the filter
it passes successively through four one-liter flasks partially
filled each with 750 ml of twice distilled water. 30 ml of HCl
are added to the water of the first flask to precipitate any
dust (Ca, Mg, etc.) which might have escaped through the
filter. A check showed that the filter was effective. The air
is scrubbed in the next two flasks filled with solutions of
NaHCO3 in order to neutralize any acid carry-over.
A final scrubbing is made in the fourth flasks which contain
only pure water. From there are filtered and scrubbed air
penetrates into the cultivation chamber. Air exits the chamber
through a double siphon, used also as a water gauge. A
positive pressure of 3 mm W.G. was measured inside the
chamber. This way, no external air intake may happen
accidentally, even with a defective gasket. No Ca, for
example, can be brought from the outside".

**(4) Study of the Variation of Calcium in Oat
Seedlings During Germination in Twice-Distilled Water, by
J.E. Zundel ~**

*Abstract:* In the course of 60 experiments
the Ca content of oat seedlings increases by 50-250% during
germination in twice distilled water.

*Introduction:*

(1) This research was carried out over the last
13 years, following the publication of works by Monsieur C. L.
Kervran. These works suggested a possibility of mutation in
chemical elements by biological means, in contradiction to the
law if immutability of matter posited by Lavoisier, being
understood that the law remained fully valid from the chemical
point of view. Kervran was kind enough to follow my work with
interest. His considerable knowledge was for me a source of
frequent and effective advice.

(2) It was by mistake that I selected oat for my
study. Initially I was looking for silica in a study which was
not pursued. Even though the oat was a calcifuge plant, it
showed a strange increase in Ca which was to become the
subject of this study.

(3) It was obvious that this study required the
elimination of all Ca additions of external origin during the
experiments. This, I tried to accomplish over the years.

(4) During the presentation of a paper of a
paper to the Academie dAgriculture de France, I was strongly
criticized for deleting experimental details. I will present
them here as accurately as possible.

*Growing Procedure:*

(1) At the beginning of my work, I was content
to use common, fodder types of oats. Later the Centre des
Semences of INRA kindly supplied me with selected seeds:
Nuprime, Flamingskrone and Peniarth, species I finally adopted
definitely for its high germinating power. The Warburg and
triphenyl-tetrazolium-bromide tests showed a germinating power
of close to100%.

(2) After trying several methods (beakers, Petri
dishes, flat and hollow plates) I selected Mutipot seedling
trays, manufactured by Ossenberg.

Each device included a tray ( 30 x 50 x 3 cm)
with a panel of the same dimensions with 73 cups 40 mm deep
which were perforated on their bottoms. The assembly was made
of PVC. The analysis of the trays showed no Ca.

(3) The seeds were sized by sight with a +/- 3%
accuracy in weight.

(4) For pre-germination, I cover the bottom of a
Multipot planter with two layers of ash-free Whatman filter
paper and I saturate the paper with twice distilled water. I
spread over it 300 selected seeds and I place the assembly in
a phytotron. Temperature is controlled at 28 deg C during the 16
daylight hours and to 15 deg C during the 8 night hours.

During the day, the phytotron is lighted from
the outside by a 400W Power Star Osram lamp. After 5-10 day
pre-germination, the seedlings are 30-70 mm high. The duration
of the pre-germinating phase, as well as the size of the
seedlings, seem to show that besides controllable factors,
there are other effects which escape me. I then assemble the
two parts of another seedling tray and I fill it with twice
distilled water to a level 4 mm above the bottom of the cups.
I pull the seedlings carefully not to hurt the radicles, and I
transplant them two by two in the tray. The complete tray
holds 146 seedlings. I place the tray in the phytotron.

(5) The seedlings are harvested 28 days after
the beginning of pre-germination. I selected this time span
because it corresponded to the average duration of the plants,
hence probably to the reserves in the seed. I pull the plants
carefully out of the planter (roots may extend as much as 20
cm between the holes at the bottom of the cells and the
underlying tray. I spread the plants on Whatman filter paper
and I dry the whole thing at 85 C for 72 hours in an electric
autoclave. I then grind the plants in a Moulinex coffee
grinder and I weigh them.

The water used for the growing process (1,500 ml
in average) is recovered and concentrated to 50 ml for
spectroscopic analysis.

*Elimination of Extraneous Ca:*

(1) The twice distilled water was supplied by
Laboratoires Aguettant in Lyon. 3000 ml of this water, reduced
to 50 ml, do not show any Ca on the Perkin-Elmer spectrometer.

(2) The glassware is made of pure silica.

(3) The crucibles are made of platinum, with the
exception of the ones used to incinerate seeds and plants. For
this work I used crucibles of pure silica.

(4) Reagents were supplied by Prolabo and were
of analytical quality.

(5) From the beginning of my work, I was afraid
of the Ca brought in by ambient air.

Therefore, I placed a tray with the same
dimensions, filled with HCl, N/10, next to the culture for the
duration of the experiment. I recovered amounts of Ca
corresponding to 2-3% of the amounts measured during
germination. As an additional precaution, I enclosed the
seedling trays in polyethylene cases and force ventilated with
clean air.

Later I had airtight cases made of Altuglass
which also had to be ventilated. Finally I acquired a fully
airtight phytotron (140 x 60 x 50 cm). Its case had a lid made
of special plexiglass, more permeable than glass to
wavelengths below 400 mm. Lighting was provided by a 400W
Power Star Osram lamp located 45 cm above the plexiglass
panel. This lamp emits a fairly uniform spectrum extending
into the ultraviolet. The light intensity at plant level was
approximately 5,000 lux. I some experiments I added a Mazda
Ultraviolet 20W lamp.

A small compressor provided air ventilation (2
liters/minute) for the phytotron. This air was first filtered
in compressed pharmaceutical cotton. Air purification was
continued by scrubbing into two flasks (2 liters) filled with
HCl, N/10, one flask of concentrated NaHCO3 and one flask of
twice distilled water. Following some objections, I replaced
the cotton filter with a Whatman Gamma 12 filter of 0.3 micron
porosity. I did not find any significant difference in Ca
fallouts using these various protective methods.

*(d) Analyses:*

(1) Samples were weighed on a 0.1 mg Sartorius
scale.

(2) Seed and plant incineration was made in
closed silica crucibles on low Bunsen flame.

After distillation, I place the crucible in a
slanted electric furnace heated to 800 C. Some objections were
raised about this temperature. However, my own experiments and
other experiments performed at Laboratoires Techniques du
Centre Technique du Papier in Grenoble, showed no appreciable
differences for temperatures of 550 C, 600 C, 800 C, 1050 C.

(3) Silica was recovered from the solution
following the Treadwell method. The precipitate incinerated in
a platinum crucible was weighed and diluted in 5 ml of
concentrated HF. After vaporization the SiO2 amount was
obtained by weight difference.

(4) The determination of Ca (and its separation
from Mg) was performed by Prof Charlots method, as described
in his *Traite de Chimie Analytique Minerale*.

(5) The determination of K was performed by
flame spectrometry on a Perkin-Elmer instrument at
Laboratoires du Centre du Papier in Grenoble.

(6) All data were expressed in milligrams per
unit of air-dried seeds or plants.

(7) Some result data was cross-checked by atomic
absorption spectrometry at Laboratoires du Centre Technique du
Papier in Grenoble. Generally the values obtained with this
method were close to my results, although I noted
discrepancies as great as 30%. Nevertheless, percentages of
increase in Ca between seeds and plants were similar to those
I had obtained.

Additional checks were performed by neutronic
activation at Centre de Recherches Nucleaires in Zurich.
Lesser discrepancies were noted, but percentages of increase
in Ca were equal to mine.

*Results:*

(1) All data the least bit suspect of Ca
contamination from the air was deleted from the table.
Consequently, I only mentioned the data obtained from
experiments in the phytotron and in the Altuglas, polyethylene
and Vitrex cases.

(2) As expected plant weights were greater than
seed weights (photosynthesis) but in an irregular fashion.
There were two exceptions: item 345, phytotron, in total
darkness, and item 353, Altuglass supplied with air without
CO2 (consequently there was no photosynthesis in either case).

(3) Ashes increased. However, item 329,
phytotron, was an exception. Ashes decreased for no obvious
reasons. In seeds, P was included in organic compounds
(phytins) which disappeared during incineration. In plants we
found P as a non-volatile Ca-phosphate. The other source of
weight increase of the ashes, was the formation of Ca.
Probably from C?, i.e., 2C + O >> Ca or 2 x 12 = 16 =
40). It should be noted that the increase in ashes is not
proportional to the increase in Ca.

(4) Mg remained identically the same. SiO2
varied slightly in either direction.

(5) Ca showed a 52-292% increase. Here was one
exception for item 342, phytotron, additional lighting with an
UV lamp and addition of CO2 in the air supply, for
which the increase in Ca was 556%. This result was checked by
spectrography and neutronic activation. I could not duplicate
this result under identical conditions (item 345). This test
showed only an 88% increase. There was an additional exception
for item 264, no Co2 and no UV. There was certainly a mistake,
but I could not locate it. I mention these two experiments as
I want to be absolutely candid.

(6) Spectrographic analyses of the water from
the culture at the end of the growth period showed an average
Ca content of 0.015 mg per plant. Normally I should have added
this amount to the Ca measured in the plants. I did not do it,
because a water analysis was not performed for each batch.

(7) K contents in the plants and in the seeds
were different. The average variation was of 10%.

*(f) Dead Control:*

Tests on dead controls are fairly difficult as
there are scores of methods to kill a seed. In every case 24
hours at 100 deg C is deadly. 24 hours at 88 deg C seems to be
marginal, as shown by successive tests at temperatures
progressively approaching 88 deg C. After germinating the seeds
for one month, there was no sign of life. Ca and SiO2 were the
same as in the fresh seeds.

I tried to kill the seeds with formaldehyde as
an alternate method. Eight days immersion in formaldehyde were
required to prevent any germination. There again, Ca and SiO2
were the same as in the living seeds. I pursued the tests with
gaseous formaldehyde. After a 7-day treatment with the gas, I
began cultivation. After 30 days there was still no
germination. The Warburg test was negative. However, the test
with triphenyl-tetrazolium-bromide was not 100% negative.
Therefore, a trace of life remained. Ca had increased by 24%,
silica was unchanged and ashes had increased by 24.4%.

Finally, I tried a fourth and more drastic
procedure. I ground the seeds. I wetted the grounds and left
them in a calibrating glass for 28 days. The ashes had
increased by 25%, SiO2 was unchanged, and Ca had increased by
12%.

This test was repeated under identical
conditions. It resulted in a 17% diminution for the ashes, in
no change for SiO2, and in a 23.5% increase for Ca.

To me, these tests do not look conclusive.

*(g) Reproducibility:*

I entertained great hopes for better
reproducibility from air-tight lids and from the purification
of the air supply after obtaining ill-assorted results over
the first years of my study. This hope was only partially
realized.

The most scattered results were obtained with
the phytotron, though it provided constant temperature and
relative humidity, and purified air supply.

Item 326b: 111%   
Item 329: 52%   
Item 358: 64%   
Item 360b: 204%

These results are indeed disappointing, but I
cannot estimate the effect of the parameters influencing the
growing process besides those which I could control.

On the other hand I could correlate the results
of the three other groups:

*(a) Altuglass:*   
Item 326a: 257%   
Item 351: 271%   
Item 343: 260%

*(b) Vitrex:*   
Item 254: 115%   
Item 260: 106%   
Item 274: 170%   
Item 271: 97%

*(c) Cultures with no photosynthesis:*   
Item 315: 54%   
Item 345: 92%   
Item 553: 84%

Therefore, the results were reproducible under
some conditions.

These results appear to show the influence of
light. The Altuglass, more permeable to light, gives higher
results than the Vitrex under solar exposure. Another
corroboration can be seen in tests 360a and 360b performed
simultaneously:

(a) additional UV; increase in Ca: 286%   
(b) no additional UV; increase in Ca: 204%

*Conclusion:*

(1) There is always an increase in Ca during the
germination of oats in twice distilled water.

(2) It is likely that this increase comes from
carbon after the pattern: 2C + O >> Ca.

It seems also likely that this process is
produced in two phases: the first being supplied by the
reserves in the seed, the second by photosynthesis.

(3) Light seems to have an important influence,
in particular wavelengths below 400 nm.

(4) Beyond controllable growing conditions one
must probably accept other influences, yet unknown to me.

(5) It is regrettable that my means (laboratory,
time and age) prevented me from performing a series of
experiments instead of a single exploratory experiment. It
would have been possible to analyze the data mathematically.
Certain discrepancies could have been explained, such as the
influence of the location of the planets during germination, a
subject being researched by several universities.

Grasse, September 1979

**[TABLE 4](tab4.gif)**

**(5) Comments on a Study by Zundel on the
Increase of Calcium in Oats During Germination in Twice
Distilled Water ~**

The point of paramount importance in this study,
issued during the summer of 1979, is the fact that each one of
over 60 experiments shows an increase in calcium in oats,
germinated in an environment devoid of calcium. This increase
varies between 52 and 292% according to Zundel, and is always
of an order of magnitude sufficient to rule out statistical
errors.

This test is a summary. It is very short and can
be quickly read by all. It reports data for only 19
experiments, including one on wheat, which I will discard. It
is one of a kind and I do not have enough precise information
from research to establish valid comparisons, It would be
tiresome to review the separate results for all 60
experiments.

It is obvious that this text shows a long
experience with chemical analysis on the part of the author.
Furthermore, his high scientific integrity makes him mention
experiments giving unequal results. This is really the value
of this impartial study: it is not the result of an arbitrary
data selection. The text opens the way to a wide discussion
because it presents the research in all its complexity.

The author does not orient his research to
obtain a reproducibility at all costs. He wants essentially to
vary the operating conditions. In spite of this, the increase
in Ca is always large. But what is the source of these
variations in amplitude? One must look more closely at the
factors which differentiate the experiments.

It is seen that the increase in calcium is
significantly smaller when carbon dioxide is eliminated,
inhibiting the photosynthesis metabolism. However, too few
experiments without or with an excess of CO2 were
performed to warrant definitive conclusions. The addition of
CO2 is very difficult to control. Small amounts
must be continuously injected. Nevertheless, various other
parameters allow one to see the importance of the
photosynthesis metabolism.

Lets compare the dry weights for the seeds and
for the plants. The photosynthesis cause the synthesis of
various carbohydrates (glicids, parotids, lipids) which
together with the CO2 derived from the air, produce
cellulosis, starch, etc. This results in an increase of dry
matter in the plant. If no increase is observed (as is the
case for items 346 and 353), it must be inferred that the pant
lived only on its reserves in carbohydrates, which were
promptly exhausted. Experiment No. 345 (darkness) had to be
interrupted after 10 days and experiment No. 353 (no CO2)
after 16 days because the plants wilted. Due to the abridged
growth, the increase in Ca was less than 100% in both cases.

The photosynthesis metabolism is affected by the
light spectrum which penetrates inside the transparent chamber
housing the culture. Glass is not the best material. It is
known for filtering some wavelengths in the ultraviolet. The
production of Ca is increased if a special UV light is placed
inside the chamber (experiments 341 and 361a). On the other
hand, results for no. 347 remain unexplained. This confirms
once more that a single experiment cannot be relied on in all
its details. Did anything escape our attention? Zundel
acknowledges this point when he writes: "besides controllable
factors, there are other effects which escape me".

Anomalies of many different origins can happen.
This is the case for wheat, for which the dry content
decreases in the plant though the amount of ashes increases.
The same happens in experiments No. 346 and 353. Sometimes the
differences may be due to an oversight; some material sticks
to the bottom of the crucible, for example, and it is only
detected during the next experiment.

Some increases in Ca may appear abnormal
(experiments No. 264 and 341) which does not necessarily mean
that there is an error in the analysis. Regarding No. 341,
Zundel comments on this aberrant increase, "as I want to be
absolutely candid". He cold not determine the cause of the
aberration. The data obtained by Zundelin his own chemical
analysis was confirmed by compatible results obtained in
following two different methods, atomic absorption
spectrometry and neutronic activation. His shows that it was
not an error of analysis, which is always possible when checks
are not made by alternate means. Was the analyzed sample
abnormally rich in Ca? Why? It is not possible to answer this
question. Was it due to an accidental contamination during the
handling of the sample? This is not proven. However, I think
that such data should only be accepted with reservation.

In these two experiments it looks obvious to me
that all this calcium could not come only from a transmutation
of K (not measured in these two cases to my knowledge). On my
side I have data on several hundred analyses showing that in
one oat seed there is not enough K to account for such a
weight increase of Ca. Could it come from Mg? It looks
unlikely, judging from past research. From silicium? I do not
think so because of various experimental reasons. Zundel
thought of another cause (2 C nuclei rotating around an O
nucleus?). I believe that no experimental research was ever
done along this speculative hypothesis. This shows, once
again, that one experiment or even two do not warrant
conclusions, even when the experimenter is highly qualified.
These 616% and 556% increases in Ca remain an enigma.

There could be some cosmic influences yet
undetected. Russian Prof Dubrov of the Research Institute of
the Globe, Moscow, mentioned in one of his books a large
variation of Ca in synchronism with a large geomagnetic field
variation. The geomagnetic field itself varies with solar
proton showers. Such causes are diverse, complex, direct or
indirect and above, little studied.

Zundel was intrigued by the 556% increase in Ca,
which corresponded to additional CO2 and UV light
(Ref.341). Is this why he mentioned having duplicated the
conditions (Ref. 347) --- except perhaps the cosmic
conditions? He only obtained 88% of increase in Ca. According
to him, "there is certainly a mistake" in one or both of the
experiments. No conclusion can be drawn; in any case, this
example raises a wealth of questions. The importance of the
filtering of the light spectrum by various materials should be
noted. Altuglas would appear to be more efficient than
Plexiglass.

Zundels study presents many enlightening
aspects and this is why I take the opportunity to comment on
it. A commentary always embodies a personal point of view. It
is subjective but necessary, I think. Zundel made sure he
presented a totally objective work. It was only right, I
think, that I showed the reader the lesson to be derived from
it, to facilitate the thinking process and to aid future
experimenters attempting to duplicate the experiments. These
experiments showed a generalized increase in Ca, slightly
larger than 100%, after a few weeks cultivation in extra-pure
water of approximate 5.7 +/- 0.1 pH (in my research). Zundel
does not state the pH of the water he used, but I know that it
was approximately equal to this value.

Note: Zundels table shows only the variations
of Ca. All these data have been checked by alternate methods
and they all point to the same conclusion. Without quoting
data in absolute value, Zundel states that average K
variations between plants and seeds can reach10%. In fact, he
had too few data, too widely scattered, to attribute a
significant value to this figure from the mathematical point
of view. For K I have the data of many other experiments. The
uncertain mature of statistics should be kept in mind; after
all, statistics measure only "probabilities". Too often one
tends to forget it. Statistical computations varied in time
and space. Today Gauss curves are little used. In France the
fashionable method is Fishers. This method introduces the
very arbitrary "Students-t". For it, Prof Baranger had chosen
a value of 1; I chose a value of 5. This means that I
discounted all variations smaller than 5%, as Baranger
accepted variations greater than 1%. In Russia the
Kolmogorov-Smirnovs tests are used: in other countries it may
be the Kuiper-Stephens method, etc.

**(1) About the Dead Control ~**

An objection was that biological transmutation
should not be observed in seeds which had been killed in dead
controls. In fact, significant, though small, variations were
observed very often in the mass of several elements when dead
seeds were placed in water just like the seeds to be
germinated. Therefore, some transmutation could not be
ascribed to biological effects and some people were convinced
there were errors in the test procedure.

Zundel also observed the same thing and he
mentions the subject in his text. However, one observation
directed him to a possible explanation of the phenomenon: it
was noted that dead seeds laid in water for several weeks
produced a cheesy small. Consequently, ferments, yeasts, or
micro-fungi had developed on the dead material. The
transmutation observed, leading to an increase in calcium,
might be attributed to the action of this microflora. This had
to be verified.

For this reason, an antibiotic and fungicidal
product, kanamycin, was added in a ratio of approximately 10-3
mg/liter. This concentration was recommended by Montuelle and
Ochin in 1967 to prevent the formation of mold on germinating
seeds. The presence of mold introduces an uncertainty. Should
the result be ascribed to the action of seeds or to the action
of the mold? Tests were made on the European type of oats,
Peniarth. In the USA, fungicidal tests were performed on the
local type Montezuma. The fungicide Ceresa was used. All Ca
increase in the dead controls disappeared.

**(2) Cosmic Effects ~**

Zundel mentions "unknown parameters" to explain
quantitative variations. In a figure in my book of 1975, I
stated that I started the germination process at the new moon
and that I harvested 6 weeks later at the full moon. I did
this in order to operate (hopefully) under comparable cosmic
conditions for each experiment though I could not establish
this point in any significant manner. At least for certain
plants, the action of the moon is well known among farmers and
gardeners. However, it was not clear for oats. The biological
transmutation seemed to depend on other causes which I did not
have the time to isolate. The action of the moon on tides is
well known, but its effect on oat seemed to be variable.

A book published by Robert Frederick around
1980, *LInfluence de la Lune sur les Culture* states
that oat is an exception, that it might be more sensitive to
some cosmic rays. However, it does not appear that the author
tried to determine which ones. One must also consider solar
action, which shows its effects on high equinoxial tides. The
effect of solar proton showers was studied in particular by
Prof G. Piccardi of the Institute of Physics and Chemistry of
Florence, Italy. In Russia this effect was studied by Prof
Dubrov of the Globe Geophysical Institute of Moscow, etc. The
research should be pursued for specific vegetal species and it
should not be limited to solar effects. This research should
be placed in the framework of biorhythms which more and more,
are shown to have an important effect on all earthly life.
This point is still ignored by some technocrats who play with
time as they see fit while giving fallacious arguments.
However, this is not the place to prove this point.

**[FIGURE 8](fig8.gif)
~ Variations of Ca after Dubrov**

**(6) Comments on Some Experiments ~**

I will not go into the details of all the
experiments performed; this would lead to tiresome
repetitions. I would like to draw some lessons from the
statistical data collected on tens of thousands of oats after
hundreds of analyses of oats after hundreds of analyses on oat
and oat seedlings. The information mentioned below is
important, because it constitutes a base of preset references
to verify if an analysis has been properly made. This is a
point of the utmost importance for all researchers in order to
avoid hasty and erroneous conclusions, some of which I noted
in the research by students in national schools of agriculture
or in public high schools which train superior technicians for
agriculture. I noted the same trend among students as well as
professors in schools of sciences in universities. I also saw
so many engineers, considering themselves as specialists or
experienced professionals, commit serious errors. These errors
looked shocking to me as these people were in known territory,
but apparently it was unknown, because they were prejudiced by
previous experience.

I believe it is important that each set of seeds
in a good stat of health and of approximately the same size.
Each set should be prepared by the same operator.
Unfortunately, in some schools several students prepare sets
of seeds for the research which to be the subject of a
dissertation or a thesis. Under these conditions, there are
unacceptable differences between tests. Sometimes I noted
weight variations reaching 20% and more, which biased the
results. Each set should be weighted to 1/10 mg for control,
as long as each set does not contain more than a few hundred
seeds. Weighing should be done to the milligram when a few
thousand seeds. The statistical average is then valid, barring
bad luck. It is advisable to always avoid seeds of a common
grade and to use selected seeds. Even if they first underwent
mechanical selection. One must do this for several reasons:

(a) There are large differences between old
species of black oats (some are still sown today, such as the
Noire de Prieure for example) and a modern hybrid light seed.
The differences can be as great as 100%. Often a species
degenerates in less than 10 years. This was the case in the
past for the black winter oats that we used. These seeds each
weighted 44 mg in average. For the light Nuprime species
hundreds of seeds showed an average individual weight of about
21-25 mg (depending on the origin).

(b) Black oats are winter grains. They grow well
only if they are sown in the fall and only if they have spent
the winter in the ground. The cold weather effect is
absolutely necessary for a good start in the spring. It is
called wintering. This phase in the enzymatic modification of
molecular structures under the action of cold is seen as an
absolute necessity, but the wintering is not yet well
understood. Consequently, one should not forget to expose the
seeds to artificial cold for several weeks when cultivating
them in a laboratory. Too often, physicists neglect this step.
On the other hand, spring oats and most light oats do not
require wintering. Light oats can germinate at any time. Some
precautions must be taken, such as varying the daily light
exposure. There may be other cosmic effects, still unknown and
little studied. Studies on this subject were made in Russia,
Italy and Belgium. In France this research was mainly done by
Prof Faussurier, Director of the Physics Laboratory at Faculte
Catholique of Lyon. He used chromatographic techniques on
metallic salt-impregnated paper in order to correlate color
changes in the paper with cosmic phenomena which had been
recorded by various observatories. There are still other
effects, still unknown, which produce barely significant
variations.

(c) In light all season oats, I stopped the
research on the Panche de Roye species for two reasons: in
this species the glume (also commonly called chaff) is well
developed. It is necessary to eliminate it to avoid
complicating the research after germination. Some agronomists
maintain that the glume must be left because it participates
in the germinating process. In my research, its effect on
mineral balances and germination power always looked
negligible.

In this variety there are two seeds in one
envelope. Nine times out of ten, one is significantly smaller
than the other. It is then necessary to open the glume to
extract the larger seed, which complicates the operation. From
the beginning this is why I concentrated my research on
so-called naked or glumeless species, such as Nuprime which is
cultivated in France and other countries mainly to make rolled
oats. Later I used Flamingskone and Peniarth because I
observed that Nuprime degenerated and was giving only 70%
germination. One should use seeds sized and selected by a
special section of INRA and with a minimum guaranteed ratio of
95%.

As a general rule, it is preferable to express
analytical data in per unit values --- one seed, one plant.
For comparative purposes one can indeed use equal weights and
use the milligram or the gram as the unit of measure. However,
when a seed does not germinate, germinates poorly or becomes
moldy, the whole data for the seed is void. Therefore, the
unit chosen should be the seed, except in experiments
involving thousands of seeds. If one seed in a set of 100 does
not germinate, the uncertainty is of 1%. Germinating ratios
for the best seeds can only be guaranteed to 95%, leaving an
excessive uncertainty of 5%. This is why I always insisted
that sets prepared for cultivation always include several
hundred seeds. How conceited on the part of researchers in
Europe and America to be satisfied with sets of 20 or 30,
sometimes less. In one experiment, for example, 6 seeds were
left at the bottom of a test tube where they poisoned each
other with the gases from their metabolism, causing a
defective synthesis of growth hormones, etc. If a single seed
out of 6 does not grow properly, a 16% uncertainty ensues.
This is unacceptable. Unfortunately, these concepts of vegetal
physiology are too often ignored by many physicists who only
reason in the mathematical abstract. Many chemists specialized
in inorganic analysis do not know biochemistry.

Personally, I always used sets of at least 50
seeds and several sets in parallel. Zundel often germinated
batches of about 145 seeds each. He analyzed each set
separately. he had two trays in operation for a total of
approximately 300 seeds.

To avoid an uncertainty of up to 5% due to
deficient seeds, it seems advisable to sue pregerminated
seeds. To this effect, a number of seeds significantly higher
than the number to be cultivated, is germinated. The seeds are
placed between two sheets of filter paper of the so-called
ashless quality. The seeds should not touch each other. The
paper is soaked with twice distilled water continually; it is
sprayed twice a day. Seeds germinate. After 4 days, the shoot
(radicles, etc.) is a few millimeters long. Seedlings, which
have germinated normally and are of comparable lengths, are
then selected.  One is reasonably sure to deal with
seedlings of equal vigor. Each seedling is carefully
transplanted in a seedling tray. An equal number of seedlings,
as similar as possible, are selected, dried and analyzed for
their respective contents in Ca, K, Mg, etc. An observation of
the results shows that there s no appreciable difference in
the weights of these minerals between fresh seeds and
pregerminated seedlings. The synthesis of new minerals starts
only after 5 or 6 days. It is therefore necessary not to
overextend the pregermination period. After 15 days, for
example, the difference in Ca is significant. This appears
clearly in the curves we traced for calcium. Other cations and
anions have also changed at the end of this period.

Hundreds of experiments showed that the relative
contents of the major minerals in the seeds varies from one
variety to the next. This is why some varieties are preferred
when looking for specific elements. In the same species,
variations may exceed 20% according to the variety. However,
the composition spectrum is a characteristic of the species.
In the same variety, relative variations between elements can
reach approximately 5%. This is due to differences in the
cultivated terrain, in soil composition, in the climate, in
average seasonal temperature, in insulation, moisture, etc.
This constant value of no more than +/- 15% allows one to detect
significant errors in the analyses. For example, with Nuprime
seeds, I found the average seed weights of 22 mg (+/- 10%)
according to the origin of the batch. The average Ca content
was about 0.025 mg, or about 1/1000th of weight of the seed.
With Peniarth seeds, the average Ca content per seed was 0.029
mg for an average seed weight of 28 mg, +/- 1 mg. These
measurements were made on thousands of seeds from the same
crop. Some years I happened to note that the average Ca
content for the same variety was lower by a few points than
the 1/1000th of the weight of the fresh seed in Ca. This is
due to climactic conditions during the year, or to the area of
origin of the crops, or to intangible cosmic factors. This is
of little importance.

On the contrary, if data differ by +/- 15%, we can
state that there was an error in the analysis, in calibration
or in the preparation of the samples for the analysis, I have
seen variations greater than 10%, which did not seem to worry
the researcher.

Often it is interesting to take into account the
normal K content and to compute the K/Ca ratio in the seed and
in the seedling. For complementary information one may also
look at K/Mg and Mg/Ca. This can lead to the detection of an
error. In oats K/Ca is found to be close to 4.8 +/- 0.5 with
minor variations according to the species. This shows that the
calibration probably is correct. However, comparisons with
other analyses are indispensable, because errors in acid
dilution may have occurred prior to injection into the
analyzer. The K/Ca ration is not an absolute criterion of the
validity of an analysis, but it often gives a good clue.

To illustrate this point: in an engineering
school a student found an average Ca weight of 0.021 mg and an
average K content of 0.078 mg per seed on 9 batches of Nuprime
oats. This gave K/Ca of 3.72, which was a little too low.
Elsewhere, several analyses of Peniarth seeds coming from the
same stock gave average values respectively of 0.0273 mg for
Ca and 0.1130 for K, or K/Ca = 4.1. This showed that the
analyses of K and Ca were only marginally acceptable and that
they had to be cross-checked, as ratios were found to vary
with the species.

In Switzerland in 1974 a study made at a
government laboratory by means of neutronic activation gave
the following respective results for each of the 5 analyses:
K/Ca= 4.5, 4.7, 4.6, 5.2 and 5.0, or an average of 4.8. It is
a good average. However, the batches included only 6 seeds
each and the accuracy of the analysis was only of 4%. The
laboratory then made a correction for the seeds which had been
poorly germinated. Computations were made on the base of 28.32
instead of 30. After correction the experiment showed an
increase in Ca of 138%. In a French agricultural engineering
school in 1973, the analysis of 9 batches of 30 seeds each (a
slightly low number) of Nuprime oats showed average K and Ca
of respectively 3.42 and 0.61 mg per seed, or a K/Ca ratio of
5.6. This was slightly too high a figure, perhaps because of
an excessive K (calibrating error?) but in my judgment
certainly because of an underestimation of Ca, due to an
inappropriate measuring procedure for Ca. The measurements
were made with a flame spectrometer. For divalent elements
there is a risk that the number of atoms with no peripheral
electrons is too small to yield reliable measurements. In a
West German university, a study made by a student on Peniarth
oats gave a Ca  content of 29.5 micrograms, a figure
which seems too high for seeds with an average unit weight of
21.36 mg. It is almost certain that an error was made on the K
content, given as 118.36 micrograms. This leads to a K/Ca
ratio of 4.0, which is too low, but shows that errors on K and
Ca can compensate each other. Therefore, it is necessary to do
several cross-checks. I will not mention any figures for a
study made in a university in the USA, because the results are
certainly wrong. Though one might have reservations on x-ray
fluorescence measuring techniques with K and Ca, this time the
error came from a mistake in the growing procedure.
Cultivation was made under artificial lighting with a lamp
giving a completely inappropriate spectrum. This resulted in
deficient photosynthesis.

A set of studies on 10 batches of Peniarth oats
coming from the same stock gave 3.9 for K/Ca. Several months
later 8 batches from the same stock led also to K/Ca = 3.9,
showing first that there had been no drift in the composition
and second that the concentrations were a little too low for
this species. Usually the average figure gravitates around 4.8
+/-10%. An error could have happened either in the growing
procedure or in the analysis. Once again we see that errors
compensate for each other, which makes cross-checks necessary.

An easy cross-check of the data in a study is
provided by the seedlings dry weight. It must be greater than
the seeds dry weight because with good growth, there is
production of carbohydrates (starch, cellulose and other
glucids, lipids and parotids) due to seedling growth. This is
due to the photosynthesis metabolism. The weight increase was
observed and measured as early as the 17th century.
Nevertheless, I noted that some French and some foreign
researchers mentioned figures showing no increase in the
weight of dry material. Some even showed a decrease. This
points to an error in the growing procedure. This did not even
catch the attention of these researchers. I will come back
later to the importance of good photosynthesis. I would like
to say here that only dry weights can be validly considered.
Long discourse on the necessity of stabilizing the weights
according to the humidity are without merit, because moisture
in the laboratory varies with the season, etc., and
comparisons between successive experiments are not valid.
Dessication standards should be set.

Even the weight of ashes is found to be higher
for seedlings than it is for seeds in most cases; this may be
attributed to methods of analysis inappropriate for these
types of studies. For example, in chemical analyses of ashes,
losses of phosphorus and sulfur, among others, during firing
are often forgotten. Some compounds become volatile at fairly
low temperatures, sometimes as low as 200 deg C, which is
insufficient to obtain good ashes. One forgets also that
calcium sulfates and phosphates in some cases are insoluble in
the acid used and they may be formed during seedling growth.
In these cases there is an excess of ashes, but the amount of
calcium is underestimated by the quantity which remains
insoluble. This shows that many chemists do not know their
trade. If hydrochloric acid, often used, does not give
satisfaction, even if it has been heated, then other acids,
such as sullfo-nitro-perhydric acid or hydroperchloric acid
should be used for the tests. However, we should not forget
that these acids are potentially explosive and they are
difficult to handle. Usually hydrochloric acid will do, but it
is a good precaution to test the potential margin of error to
see if it is acceptable. Physical analytical techniques
applied to dried, instead of incinerated, powders can be used
to circumvent these difficulties. However, with some
techniques involving the use of physics instruments, solution
is still part of the procedure and the dissolving power should
be taken into consideration. No such problem occurs with
spectrometers when the powder is sparked.

Some of the figures mentioned in various studies
are so obviously wrong! Such is the case in a study made in a
German university on 192 Flamingskrone oat seeds and 190
seedlings. After 49 days of growth the following data was
reported:

Average dry weight of each seed: 21.77 mg, and   
Average dry weight of each seedling: 32.67 mg.

Data reproduced without comments.

There is certainly an error. Furthermore, the
contents mentioned for Ca, mg and K are questionable. All
these figures are smaller than corresponding figures for the
seeds, though the total weight increased. The Mg/Ca ration is
completely abnormal. Other cross-checks show that the figure
for Mg is much too low, and that the figure for Ca is too
high. Evidently this student did not master the analytical
technique he was using. In an American university we saw
similar results, although the supervising professor did not
make any comments. Every result should be cross-checked.

In another university department the following
values were quoted in micrograms, per Peniarth seed:

K = 11.4; Mg = 33.7; Ca = 29.5, which gives:   
K/Ca = 4.0; K/Mg = 3.5; Mg/Ca = 1.1.

K/Ca is almost normal. This might lead one to
believe that K and Ca were fairly accurately measured.
However, if:

K/Ca = 4 and K/Mg = 3.5, it is impossible to
have Mg/Ca = 1.1

A French researcher told me that he found the
following relations:

K = 0.113; Mg = -.030; Ca = 0.027   
K/Ca = 4.1 (about normal); K/Mg = 3.6, and Mg/Ca = 1.1.

These values are very close to those quoted
previously and show an error of the same order of magnitude in
Mg.

In official tables for an unidentified species
and following analyses by purely chemical means, K/Ca is given
as 7.03, which is too high. This shows that the value measured
for Ca was too low, because Mg/Ca is given as 2.5. If Ca is
too low, then Mg is also too low, as the K/Mg is given as
equal to 3. At the minimum the chemical analysis of Ca and Mg
should be checked. It is likely that Ca and Mg were not
properly separated (probably with oxalate?). This would
explain the errors in the three reports mentioned.

Experiments correctly performed show that K + Mg
+ Ca + Na is approximately constant for a given species and no
additional fertilizing elements are brought in. Whatever the
species, one can favor any cation by selection. Na varies a
great deal in relative value (often 50-60%), but we neglected
it because it is very small in absolute value in vegetals.
Therefore, it is permissible to only measure and compare K +
Mg +Ca. Many experiments showed that Mg does not vary
significantly in oats. For oats it is therefore sufficient to
compare only the values of K + Ca to detect gross errors in
tests or analyses. I also neglect Si, which shows small
variations in relative value. However, these variations are
often interesting to study, as observed by Vauquelin in 1799.
Please refer to my book of 1975.

By rounding off the numbers in the previous
example, one obtains K + Ca = 0.14 mg in the seeds as in the
seedlings. This leads one to infer that the analyses are
correct in both cases (there is a small error for Mg). On the
other hand, I noted an error in a study made in a foreign
university in which K + Ca was given as 0.154 mg for seeds and
only 0.145 mg for seedlings. In this test there was less Mg in
the seedlings as well, and the researcher did not notice that
all the elements were in smaller quantities, although the dry
weight had increased by approximately 50%. With such comments
one can appreciate the validity of experiments. If Mg is also
measured, we will note again that the three ratios, K/Ca, K/Mg
and Mg/Ca help to determine which cation was in error. I shall
mention again that I gave the following figures for the
Flamingskrone variety:

Seed: 0.1130 K + 0.0273 Ca = 0.1403 Total   
Seedling: 0.0799 K + 0.0590 Ca = 0.1389 Total

By rounding off to the third decimal:

In the seed the total is 0.140   
In the seedling the total is 0.139,

which is a close match. We can refer to numerous
and various cross-check performed on tens of thousands of
seeds of various species. However, in seedlings, the
dispersion of the measurement is often considerable due to
differences in growing procedures: light spectrum through
various materials, etc. In any case K + Ca should remain
nearly the same in the seed and in the seedling. If not, one
should try to determine the cause of the error, if possible.

**(7) Reservations on Some Analytical
Techniques ~**

Several times I pointed out that a physical
analysis technique, requiring the most modern and
sophisticated instrumentation, could not always be accepted
without reservations. One must always cross-check the results
by completely different techniques. For example, I mentioned
the case of an error due to a wrong dilution during an
analysis by atomic absorption spectrophotometry. For
comparative purposes, the gas pressure fed from a liquid
acetylene supply, the gas flow to the Bunsen burner, etc.,
should be recorded. So should the lanthanum concentration in
the buffer solution, which prevents interferences by some
unwanted elements. I also pointed to some sources of error in
electronic transducers connected to a computer. Each class of
instruments has limits. I do not question how the figures were
obtained, however they are not always reliable.

**(8) One Example With X-Ray Fluorescence ~**

There are crazes, fashions and also habits
peculiar to the laboratory or to the operator. In Figure 9, I
show an example of a curve obtained by x-ray fluorescence from
dry ground oats in the nuclear physics laboratory of an
American university. It was taken from recording made in 1976
of the simultaneous measurements of K and Ca. The continuous
curve corresponds to the actual measurement. It seems that,
starting with an atomic mass of 41, the K peak has a steeper
slope. Studies have shown that this is due to the Ca curve
which contributes to the sharp rise in the K curve. The K peak
is not a line. It spreads widely and masks the curve for Ca.
Computation factors fed into the computer are somewhat
arbitrary, because they may vary according to the material
analyzed. For this reason the final result may be right or
wrong. A cross-check by a different technique is necessary, no
matter how carefully the calibration was performed (as the
zero adjustment of a pH meter, in the case of a relatively
simple instrument). The values for the K peak and for the Ca
peak (dotted line) are good. A similar analysis was performed
after the germination of the seeds. For the species tested, it
showed an increase in Ca of 125% corresponding to an
equivalent decrease in K, which confirmed the correlation
between the two elements.

**[FIGURE 9](fig9.gif)
~ Analysis of K and Ca by X-Ray Fluorescence**

**Additional Information On Physical
Phytochemistry During Germination ~**

Too many physics specialists are tempted to
simplify vegetal biology processes and they select germination
procedures in which normal reactions cannot develop. This
results in distorted data. I do not intend to give a detailed
study of this topic, but I want to describe a few steps in the
preliminary study. This study is essential if valid
experiments are to be achieved.

**(1) Summary of the Germinating Phases of
Grain Seeds ~**

When the seed is exposed to a temperature of
15-20 deg C and to the proper moisture (close to 100%), the
embryo produces which migrate toward an external layer of the
seed, located under the tegument and made of aleurone cells.
There the hormones cause the formation of various types of
hydrolytic enzymes which circulate between the cells in the
core of the seed (endosperm). These cells constitute the
reserves of the seed. The enzymes destroy the walls of the
cells and transform starch and proteins. Under the action of
diastase, starch is transformed into various sugars.

An enzyme cannot act if the cell structures
constitute an impermeable barrier and prevent the enzyme from
reaching the substances it is supposed to transform. This is
why some enzymes must first transform the walls of the grains
of starch. There is, therefore, a programmed sequence of
enzymatic actions. The product of a reaction with an enzyme
constitutes the substrate for the next reaction, which
includes a spatial modification of the molecular structure.
Successive enzymes are prepared and they become available at
the right time, so that the effective section of interaction
with cosmic neutrinos is continuously changing.

In the fresh seed, the external envelope, or
tegument, provides a mechanical protection for the endosperm,
which constitutes the reserve of food. The embryo is located
at one end, and is also protected by the tegument, from which
the roots and leaves will sprout. As early as the second day,
the embryo synthesizes a growth hormone, gibberellin. This can
only be done in the presence of water and under favorable
temperature conditions. It acts as some sort of a messenger
for RNA which reaches the aleurone layer in a few days (1-2
days). There it produces the synthesis of hydrolytic enzymes,
which will transform the structure of the grains of reserve
proteins. These proteins include avenin (in oats) in addition
to structural proteins, the glutelins. The endosperm cell
walls are mainly constituted of beta-glucane chains, which are
glucose polymers, close to cellulose, linked by very short
peptid chains.

One of the effects of seedling growth is the
decomposition of these various constituent elements into small
molecules. A few hours after the seed is moistened, the peptid
links between the beta-glucane elements are broken by an
enzyme, carboxypeptidase. The degrading process develops step
by step. A whole series of enzymes act specifically on the
internal links as soon as they are in contact with the
products decomposed by the previous enzyme, and they produce
various sugars. During that time, other still relatively
unknown enzymes decompose the pentosanes, breaking the walls
of the starch grains. Once the cellular walls are broken,
other proteins interact with starch, which is converted into
glucose. During this time, the gibberellin migrates to the
opposite end of the seed (the distal area) over a period of 10
days, transforming almost all the aleurone cells at the back
of the seed. By that time almost all of the starch has been
structurally transformed. The transformations are by then
macroscopically significant, to the point of making variations
in the seed chemical composition measurable. We published
curves showing the abrupt changes which happens after about 10
days of germination.

After two days, the tip of the embryo starts to
emerge from the tegument. On the average, the radicle length
is 2-3 cm after 4 days. The embryo has eaten close to one-half
of the starch by this time. After 8 days, the radicle has 608
offshoots and almost all the starch has disappeared. Enzyme
activity is then fully accelerating and analyses show very
significant biological transmutations. It is at this time that
the photosynthesis contributes its effects as leaves are
already well developed. This results in a sharp rise in the
calcium content shown in our curves around 8-10 days. Analyses
made at short time intervals show that seed compounds are not
appreciably modified until the fourth day. For the purpose of
comparing Ca contents, after 28 days for example, it is
legitimate to select the seeds which sprout well after 4 days
of pregermination. It is understood that no Ca should be
brought from the outside during that time.

**[FIGURE 10](fig10.gif)
~ Grains of Cereal in Germination**

**(2) Average Curve of the Increase in Calcium
of Oats After Germination ~**

To my knowledge, about 60 experiments were
performed over the last 10 years on the germination of oats to
study the increase in calcium in hydroponic cultures. This was
done over a period of several weeks without external addition
of Ca.

These experiments required over 400 analyses by
different physical or chemical techniques. These analyses were
made on tens of thousands of seeds or seedlings. The increase
in Ca is measured by comparison after analyses of a seedling
and of a seed similar to the one from which the seedling
originated. This is to say that the phenomenon was studied for
a long time and that it is firmly established.

It seems of interest together the results from
approximately 40 experiments especially well performed on
light hybrid species only. Their seeds are small and generally
more homogeneous than the big black seeds produced by old
varieties. Nuprime, Flamingskrone and Peniarth varieties were
primarily used in these experiments. The seeds weighed
approximately 20-30 mg according to the species and the batch.
They were calibrated to 1 mg after selection in batches of
100-300 seeds. Some analyses involved batches of more than
1000 seeds. The units retained here for comparative purposes
are the seed and the seedling grown from a seed, because they
represent the minimum biologic quantum of enzymatic action. If
a seed does not germinate, the whole weight of the seed
remains inactive. However, seed weights should always be noted
to allow comparisons between batches of various origins and
varieties. In the light hybrid varieties considered, the Ca
content represents approximately 1/1000th of the weight of the
seed. This figure is based on tens of thousands of seeds. A
fresh seed with an average weight of 25 mg will have roughly a
calcium content of 0.025 mg.

Figure 11 summarizes the data obtained after
about 40 experiments. This does not mean that each point of
the curve corresponds to an average of 40 analyses (by
different techniques and on several varieties). Most
experiments involve only the analysis of Ca in non-germinated
seeds, and then on the seedlings grown from similar seeds and
harvested after 4, 5 or 6 weeks. Experiments, in which
seedlings were sampled after 2-3 weeks, are few; the majority
of the data is related to seedlings cultivated over 4-7 week
periods. However, data collected either during a short
experiment or sampled after a few weeks from a batch left
under culture, are compatible and they allow one to draw the
curve in the appendix.

This does not mean necessarily that every figure
found for Ca in a new experiment or a given duration will be
located on this curve. It is an average for several varieties
obtained by means of various analytical techniques. The
dispersion inherent to biological batches of different vigor
should always be taken into consideration. Nevertheless, the
effects of all these elements should not cause a variation
greater than 15-20% from this curve even if they are
cumulative. Hence, this curve can be used as a guide in this
type of research, to detect a major error in the procedure or
in the analysis. We established it for this purpose. It is a
piece of information and it gives an indication about the
magnitude of the phenomena involved in the production of Ca
under the effect of growth hormones. One should note the
asymptotic trend of the curve after 2 months of growth (these
spring oats are normally harvested 4-5 months after sowing).
The growth metabolism is only active during half the life of
the plant. Growth hormones (gibberellin, auxins) synthesize
the enzymes for the plant anabolism during germination. The
curve shows that the Ca formation is quantitatively linked to
the activity of growth hormones until exhaustion at the point
of maturity (1)

[(1) The diminishing in growth of Ca production
may come from Ca saturation in the plant which, in turn,
affects the enzyme. The saturation is reached after 8 weeks
with a K/Ca ratio approximately equal 1.5. In the seeds the
K/Ca ratio is approximately 4.5. The transmutation of K into
Ca stops when the two elements are about equivalent in weight.
That would be at the time of maturity, when the growth
hormones effects have ended.

**[FIGURE 11](fig11.gif)
~ Augmentation of Ca in Oats**

However, one should not infer that the
production of enzymes alone can explain the energy balance for
the transmutation which leads to the production of Ca. The
enzyme production constitutes an essential element because a
seed which does not germinate, does not produce any biological
transmutation. The question of energy does not have a place
here. I only wished to present an objective document on the
data obtained as reference for future research.

---

**Chapter 4**

**Photosynthesis**

In one of my early books I mentioned a 17th
century experiment made a Flemish physician, Jean-Baptiste
Helmont, in which he planted a 5 lb willow tree in a planter
containing 200 lb of soil. The planter was covered with a lid
with two holes, one for the trunk and the other for watering
the tree. The purpose of the lid was to prevent any changes in
the weight of the soil by dust from the atmosphere. After 5
years the tree was uprooted and weighed. It weighed 164 lb.
However, the weight of the soil had only decreased by 2 oz.
Helmont did not find any satisfactory explanation for this
observation. Photosynthesis was then unknown.

For a long time the study of the phenomenon
remained sketchy. From time to time crazy results were quoted
in quasi-official documents, without attempted justification.
For example, it was stated without comment that soils were
improved by bamboo trees (1969). Oureschi, Yadar and Prakash
observed that the species Bambusa Tulda gave back to the soil
more calcium than it took. Other bamboo species, such as *Nechouzeana
Dulloa* and *Oxytenanthera Nigrociliata*, "give
back more magnesium" --- from *Nature and Resources* No.
4, p. 15 (1975), UNESCO Publications.

But it was only during the 70s that the
mechanism of photosynthesis was studied more thoroughly. It
was finally understood why monocotyledons exposed to
atmospheric carbon dioxide gave compounds which differed from
compounds found in dicotyledons, C4 compounds in the first
case versus C3 in the second. This explained differences in
behavior and yield among various families. Some plants growing
on salty soils follow the C4 cycle due to a specific effect of
Na. This is also true of many weeds. They take more carbon
from the ambient air, and therefore need less fertilizer than
plants with a C3 cycle. In addition, they produce more dry
matter and consume less water. We will study the role of
photosynthesis more closely, a subject still ignored too often
by many agronomists, because it was not taught to them.

**(1) Effects of Artificial Lighting in the
Photosynthesis, for the Study of Transmutations by Cereal
Plants ~**

Many experiments were performed in various
countries at various times to study the transmutation of
particular elements during plant germination.

Usually they were performed under natural light.
With the development of this research, a problem related to
the use of artificial light arose. It was used in particular
for the studies on the germination of cereal grains,
especially of oat and wheat.

These grains, as well as barley and rye, are
said to have long day cycles. This means that they grow in
daylight and reach their maturity shortly after the longest
days in the year. Ideally they need 13-15 hours of daylight in
French latitudes, 16 hours in more northern latitudes.

For this reason, the research on transmutations,
which are produced at the peak of the enzymatic activity
(strong growth of the plant) is distorted when laboratory
experiments are run outside the spring season. Transmutations
are indeed observed during germination in sunlight, at
different periods in the year, but they are not quantitatively
equivalent.

It became clear then that artificial lighting
would be beneficial, even in spring, in a room insufficiently
exposed to daylight. It would also be useful for studies made
at other periods of the year to extend the action of sunlight.
It would enable the experimenter to have an artificial day of
controllable length, so as to always operate under optimal
conditions for photosynthesis in all locations and seasons.

**(a) Photosynthesis ~**

We are not trying to summarize here what
photosynthesis is. We are restricting this word to mean the
action of solar rays on the chlorophyll metabolism. This does
not encompass the whole of photobiology. We will not discuss
more specific subdivisions such as phototropism, which
manifests itself by an orientation of the pant toward light.
As a point of interest for what follows, we will note that
blue rays are most active for phototropism. Oat plants lit
laterally with blue light bend toward light. As a point of
interest for what follows, we will note that blue rays are
most active for phototropism. Oat plants lit laterally with
blue light bend toward the blue light source. There is an
antagonistic effect with longer wavelengths. If the other side
of the oat seedling is lit with a green or yellow-green light,
the seedling grows vertically. We will not touch either on
what is called photoperiodism, or the influence of alternating
periods of light and darkness. We shall recall that the
inverse reactions of photosynthesis are produced in darkness
by the plant. Photosynthesis achieves the global effect of
taking carbon dioxide from ambient air, fixing carbon in
various organic compounds (carbohydrates) and ejecting the
oxygen generated from the water generated from the water
supplied to the plant. In darkness, the plant takes oxygen
from ambient air and ejects carbon dioxide. This is
respiration, which only becomes important in darkness, because
there is no photosynthesis. Furthermore, we will not
discriminate between the optical spectrum of photosynthesis
and the sensitivity of chlorophyll to various wavelengths of
the solar spectrum. The curves for these two phenomena are
very close, but they do not coincide, because photosynthesis
includes additional reactions beyond the metabolism of
chlorophyll.

It is essential to remember tat our eye and
plants have much different sensitivities to various
wavelengths of the solar spectrum. It is not sunlight, as we
see it, which should be used as a criterion in looking for the
artificial light source closest to sunlight. We must find out
to which parts of the solar spectrum chlorophyll and the whole
plant react best. A difficulty stems from the fact that our
measuring instruments, luxmeters for example, are calibrated
from the effects on our eye. Brilliance and lighting units are
defined by optical effects. It is the eye which is the final
standard of measurement. In fact, there are two completely
different aspects. This appears obvious in Figure 12a where we
have drawn the curves of maximum sensitivity to wavelengths
for the eye, and for photosynthesis.

**[FIGURE 12](fig12.gif)
~ Lamp Spectra**

Wavelength is expressed in nanometers (nm) or
billionths of a meter. This is the unit most commonly used
today, because it conforms to the metric system. It is the
thousandth part of a micrometer (or a micron). The millimicron
and the nanometer are equivalent, the second being more common
in spectrometry. Some people use the angstrom unit, which does
not belong to the metric system and which for this reason is
being progressively abandoned. One anstrom is equal to 10
nanometers. People using microns will divide by 1000 the
figures quoted here in nm.

Visible light extends in principle from 400 to
700 nm. These are average limits. In fact, some people can see
down in the violet as low as 380 nm; others see up in the red
as high as 760 nm (sometimes up to 800 nm). By convention, the
near infrared (IR) encompasses the 750 (0r 800) to 1200 nm
band. The far IR covers approximately the band up to 3000 nm.
Beyond this wavelength the action of solar radiations is
negligible and its effects on photosynthesis is not
considered. The longer the wavelength, the lower the frequency
associated with the wave. The photons with the most energy
correspond to high frequencies, hence to sorter wavelengths;
they are the photons in the blue, violet and ultraviolet (UV).
Rays with wavelengths shorter than 380-400 nm are rated as UV.

The solar spectrum includes UV with a minimum
wavelength of 390 nm (or 288). Shorter wavelengths are stopped
by the ozone layer surrounding the earth. Life on earth is
only possible because of the filtering out of the rays of
shorter wavelengths. In fact, shorter UVs are used for their
bactericidal effects. They are life destroyers (the energy of
their photons is such that they decompose living molecules).

For photosynthesis one should not look for lamps
with rays shorter than 290 nm. Even in photosynthesis no
action is observed from rays with wavelengths shorter than 380
nm. In fact in nature, in the open country, there are rays
between 290 nm and 380 nm. What is their purpose for the
plants? They may act on pigments and on protovitamins, in
animals as swell as in plants. There are few, quantitatively,
and their energy seems to be weak. Their study is indeed
difficult. In order to do this, one must find solid substances
to make prisms transparent to these wavelengths and opaque to
others. The molecules of monochromatic substances should not
be ionized by the energy of the photons in this band. Such
materials are delicate. Therefore, we do not know what nature
does with the rays in the 290-380 nm wave band, perhaps
because their study presents too many difficulties. We are
noting this, but we will not come back to it, because the
present document is only related to the aspects of
photosynthesis which we can understand with the help of
todays instrumentation.

In fact, it seems that photosynthesis is altered
by wavelengths shorter than 380 nm when they are of high
intensity. This is the case of the 365.4 nm mercury ray. It
penetrates through quartz, but it can be stopped by glasses of
various compositions. For the purpose of photosynthesis, glass
filtering UVs below 375 nm should be used in mercury discharge
fluorescent lamps (or tubes) when fluorescence is produced by
the internal coating. When the arc is produced between two
electrodes in mercury vapor, the discharge tube must be made
of quartz so it does not stop the UVs, which will trigger
fluorescence in the special powders coating the inside of the
light fixtures external glass surface. The glass shields the
plants from UV rays (below 375 nm), but it does not stop
fluxes in the 375-400 nm wave bands which are essential for
some phases of photosynthesis. The intense 253.7 nm ray is
completely stopped by the glass and it is used for the
excitation of fluorescence.

On the other hand, IR rays have weak energies.
Their energy is essentially thermal. It is sufficient that the
glass remains transparent to rays up to about 1000 nm. Glass
is opaque to wavelengths in the far IR, which explains its use
for the greenhouse effect. The near IR penetrates inside, and
the ground reemits a heat of a longer wavelength which cannot
get out.

The radiation of red and IR rays up to 780 nm
controls the opening of the stomata of the leaf, hence its
respiration and its transpiration. Beyond this point, a
counter effect is started. Leaf moisture loss ad gas loss
should not become excessive. Beyond 780 nm, photon energy is
low; this is why the curve of photosynthesis intensity remains
close to the horizontal axis (see curves in Figures 12a and
12c). The thermal agitation due to red and longer wavelengths
excites electrons in the atoms of the organic material of the
leaf. However, the energy is too low to permit the extraction
of the electrons which have moved to less stable orbits.
Electrons do not move from atom to atom as they would under
the stronger energetic effect of blue and shorter wavelengths.
This constitutes the chemical effect of blue, violet and UV
rays on the molecules prepared by the thermal effect of red
rays. It can be seen from the curves in Figures 12a and 12c
that the peak of energy is higher on the side of short
wavelengths than it is on the side of long wavelengths. By
contrast intermediary wavelengths in the green and yellow have
no significant influence on photosynthesis. On the contrary,
under artificial light in an apartment, for example. Our eye
is most sensitive to yellow. Consequently, lamps designed for
industrial or domestic lighting should not be used in
phyto-optics. We note this point, which is sometimes
forgotten.

**(b) Characteristics of Some Lamps ~**

We will not list the tens of lamp types used for
artificial lighting in agriculture, horticulture, etc. They
are described in many published works. We used a wide
selection of lamps, incandescent, discharge, fluorescent and
mixed, because not all plants are sensitive to the same
wavelengths. This fact is well known and it is used in the
design of commercial products. Most often it is known only
empirically and the related information is marred by many
errors. We evidenced this during experiments on the
transmutations observed on particular elements during the
germination and the growth of cereal plants.

At the beginning of the 60s some agronomists
recommended lamps of the warm white type or sometimes warm
white deluxe. I believe this is a mistake. Figure 12b shows a
diagram of the characteristic emissivity for these lamps. The
rectangles show the primary characteristic rays of excitation
of the fluorescence. The continuous curves characterize the
spectrum outside the lamp. It is obvious that these lamps are
very deficient in the blue-violet and too strong in the hot
colors, the reds. We saw that red has an effect on the control
of transcription, hence on gas exchanges. Transpiration
depends on the energy in the blue for about 40% and on the
energy in the red for 60%. However, plant growth and
development and the chemical reactions which cause the
synthesis of the organic compounds constituting the plant, are
only active in the blue-violet and the UV. Growth hormones
(auxins, etc.) are also synthesized under their action. We are
not surprised that phytobiologists, under their action. We
were not surprised that phytobiologists, after following
erroneous procedures of 15 years ago, got underdeveloped
seedlings. Their plants grew only a few centimeters after
several weeks as seedlings of 25-30 cm height are obtained
under optimum lighting in the same time span for wheat as well
as for oat. I have no base of comparison for other grains.
Without blue rays, wheat assimilates nitrogen and potassium
with difficulty. Contrary to what happens under normal
cultivation, the plant cannot assimilate K correctly,
therefore no transmutation of K into Ca can take place. The
circulation of water and mineral salts inside the plant is
normally made because of the long wavelengths. It is only a
transfer, which does not involve any physical or chemical
transformations. These are only triggered by wavelengths in
the blue through UV band.

The color temperature of the warm white lamp is
of 3,500 K (or color 29 on the Phillips scale, as compared to
34 for the Warm White Deluxe. This figure of 34 corresponds to
a radiated power of 7.1 watts, as the lamp of color 29, which
radiates in the red, has a peak of 8.1 W.

The radiant flux is greatest for the Daylight
Lamp, but its flux in the red is too low. Its flux in the blue
is significantly higher. It is felt that it gives objects a
bluish cast. This is why these lamps were replaced with lamps
which gave a warmer light (more red, less blue). These lamps
have a radiating energy in the blue which is significantly too
low for photosynthesis. They are lamps for home lighting. We
will note that these lamps strongly radiate in the
intermediary spectrum, which is adapted to our sensitivity and
appropriate for interior lighting. However, it is a waste for
photosynthesis.

**(c) A Well Designed Lamp ~**

One can change the shape of the fluorescence
curve by changing the nature of the powder coating the inside
of the discharge lamps. This can also be done by changing the
nature of the rays triggering fluorescence in the compound
coating the inside wall of the quartz discharge tube.

Iridium radiates in the 411-450 nm band, hence
in the blue. There is even a very weak ray of 380 nm in the
UV. There are also two important rays around 680 and 690 nm.
Two other elements are also used to trigger fluorescence:
thallium which radiates at 534 nm and sodium at 588 nm.
However, their intensity in the yellow must be corrected with
too many blue and red wavelengths to be practical. These lamps
are now of little use. Magnesium arseniate, fluorogermanate
and manganese compounds were also used for the fluorescent
coating. Iodine gives an intense ray at 577 nm, at the limit
of the yellow and green. Because of this, it is used in large
lamp fixtures for public lighting and automobile headlights.
However, iodine has other useful properties. It also gives a
ray in the UV and it is added in some fluorescent lamps as
such, or as metallic iodides. Unfortunately, almost all the
known spectra are not appropriate for phyto-cultivation, at
least in studies on elementary transmutations. These
transmutations cannot happen with spectra of the types
represented in Figure 12b. I shall not comment on the Osram
Power Star lamp used by Zundel, as I had no experience with
it.

In Figure 12c, I am showing the spectrum of a
lamp specially designed by Societe des Lampes Claude in
France. For over 15 years lamps of the types in 12b proved
inadequate. Societe Claude markets lamps rated to 250 W and to
400 W. I was gratified that they lent me units of the 250 W
model giving 12,000 lumens. Lets not forget the relativity of
the light flux concept for the eye. A close correlation
between lamp and photosynthesis spectra is the only
consideration which counts. In this oblong lamp, electrical
discharges are produced in Hg at low pressure between
electrodes inside a quartz tube. The tube is closed and it can
be mounted in a horizontal position. It is surrounded by a
surface made of special glass and internally coated with a
fluorescent salt. Various compounds were tested such as a
ytrrium vanadiate doped with europium; other more common
compounds, such as phosphates, aluminates, etc., could be
used.

Rays radiated by the discharge tube, such as the
253.7 nm Hg ray, trigger the fluorescence in the coating. Due
to the filtering effect of the glass, the 404.7nm and other
rays of longer wavelengths are the only ones radiating outside
the lamp. The spectrum distribution is shown in Figure 12c. It
is seen that two Hg rays are located toward the end of green
and in the yellow. They have little positive effect on
photosynthesis and no negative effects in general. Their
effect is to give a light which is relatively white to the
human eye, a useful point in greenhouses. There, flower and
leaf colors should look the same as under solar light, so that
the general state of health of the plants may be gauged in one
glance.

The Phytoclaude 400 W model lamp, which was lent
to us, gave the following radiated flux in watts for various
bands:

Wavelengths in nm: 400-450 ~ 450-600 ~ 600-700 ~
Total: 400-700   
Flux in watts: 10.2 ~ 2.29 ~ 0.92 ~ Total: 13.93

One clearly sees the considerable advantage
presented by this lamp: approximately 10/13 of the energy
transformed in light is in the 400-450 nm band, which is the
active part of the spectrum for photosynthesis. The Warm White
Deluxe lamp radiates only 1.7/13.4 of its energy in the
400-510 nm band. In fact, the 520 nm wavelength is already in
the green, hence has little effect on the photosynthesis. The
total radiated energy is not a sufficient criterion; the
important point is the band distribution. Even if the band is
extended to 510 nm, the Warm White Deluxe lamp gives 6 times
less energy than the Phytoclaude lamp gives in the blue-violet
with similar total radiated energies (13.4 W vs 13.7 for the
Phytoclaude lamp).

**(d) Cultivation in a Closed Chamber with
Carbon Dioxide ~**

Commercial cultivation of flowers and some
vegetables under phyto-lighting is usually done in large
greenhouses. Laboratory studies are often made in small rooms
and even in small cabinets designed for this purpose.
Sometimes they are made in the corner of a laboratory under a
plastic shelter which lets light in but stops dust. In all
cases the plants are placed in an atmosphere renewed naturally
or by mechanical means.

For more precise studies, one can use closed
chambers maintained at a slightly positive pressure (3 mm W.G.
for example) by a filtered air supply. Chambers normally
include a removable panel to allow the handling of the
equipment and seedlings. Panels are fixed in place by gaskets
and screws. They are sometimes made of polymethylmetacrylate
(plexiglass, for example) transparent to the right bands of
the solar spectrum. These chambers can be exposed to solar
light or to phyto-lamps. Even better results are achieved with
Altuglas.

When extra precautions to prevent any external
contamination are deemed necessary, seedling trays are
supplied with air by an electric centrifugal lamp delivering a
positive pressure. The air passes through a filter which
retains practically all the dust, as we verified. Sometimes
even more stringent precautions may seem necessary. Lets take
the case of the study calcium variations during the
germination of grains. One must operate with water and air
absolutely devoid of Ca variations during the germination of
grains. One must operate with water and air absolutely devoid
of calcium to obtain an accurate Ca balance before and after
germination. Sometimes the Ca was measured by neutron
activation techniques in the seeds. Unfortunately, seeds
exposed to non-lethal doses of neutron radiations were
sometimes irradiated for the experiments. This was a mistake.
Seedlings are watered with twice distilled water, free of
measurable Ca. After several weeks the plants are analyzed by
various methods. To prevent any dust from entering the plant
chamber the supply air is bubbled through a flask partially
filled with an acid solution (30 ml HCl to 750 ml of twice
distilled water in one-liter flask). The air is then pushed
into the hydroponic cultivation chamber. Any lime particulate
in suspension is dissolved in the acid solution. With the
positive pressure, no external air leakage into the chamber
can occur, even if a gasket is defective. Any leakage would be
detected with the water gauge at the air intake.

With these precautions, numerous studies on oats
showed that there was a production of calcium by the seedlings
during their growth.

Additional precautions were taken for studies on
oat and wheat in particular concerning the purification of the
air supply. Behind the flask with the acid solution were added
two flasks containing a NaHCO3 solution and one
flask containing twice distilled water for a final scrubbing.
The role of the basic solution was to neutralize any acid
carry-over without trapping the CO2 contained in the air
supply. These represent the most elaborate precautions which
can be imagined. This was necessary in order to counter
prejudiced objections, which ascribe all increases in calcium
to an external source. Even with such a wealth of precautions,
there is an increase in Ca which can exceed 100% of the total
Ca contained in the seeds germinated.

Tested were made on wheat in a controlled
atmosphere with a CO2 concentration of 0.08% and a
lighting 4,000 lux. With 10,000 lux it was possible to raise
the concentration of CO2 up to 0.013%. Under
intense sunlight it is possible to reach 70,000-80,000 lux,
but the CO2 concentration cannot be increased in
the same proportion. There is a saturation phenomenon in the
plant for various reasons. Principally because other functions
must follow: water and mineral salt circulation, gas
exchanges, etc. For wheat, the optimum concentration seems to
be 0.5-0.6% or approximately 15 times as much as in ambient
air, and it produces an assimilation about ten times higher
than normal in the atmosphere. We shall remember that the lux
measurement is of little value as it refers to the human eye.
Studies were made up to 20,000-30,000 lux and even more, but
this is not economically feasible.

On the other hand, good results were obtained on
wheat in a controlled atmosphere including 0.14% CO2, which is
four times the natural concentration. These results were
obtained in a glass chamber in sunlight without additional
phytolighting. More straw, heads and grain were obtained and
the heads were larger. This shows that the development of
grains is limited by the relative scarcity of CO2
in the atmosphere. In a controlled atmosphere CO2
concentrations 4 times greater than in ambient air can be
used. We shall note that most published data related to this
subject are wrong because they are based on Calvins cycle. We
shall comeback to this point.

One barley species shows great resilience to
intense irradiation by a light source of 460 nm. In this band,
10,000 kiloergs/cm2 are required to stop flower
formation. By contrast, it takes only a much smaller amount of
energy (about 1,000 kiloergs/cm2) at 480 nm to stop
the formation of soybean flowers. Consequently, in the open,
barley blooms during long days and soybean plants bloom during
shorter days, when the intensity of the sun has subsided.
Usable energies in the read are always low. Barley needs only
300 kiloergs/cm2 at 700 nm. The figure is the same
for soybeans. Barley and soybeans show similar effects to
green light. Grains use 10 times as much energy in the blue as
the legumes. This must be taken into account when using
artificial light. There is no general rule; each plant species
should be studied separately.

**(e) A Few Additional Comments on
Photosynthesis ~**

I will deal here with a subject which, to my
knowledge, has not been presented in any published work. Our
knowledge of the photosynthesis phenomena is incomplete and
agricultural engineers should hold reservations regarding some
so-called authoritative statements. We observe some results,
but we cannot explain the complete sequence of reactions which
lead to them.

The most common mechanism for explaining
photosynthesis is the Calvin cycle. This cycle was adopted
with much enthusiasm and too little discernment, because there
was no acceptable explanation previously. Calvin started from
existing intermediary organic compounds, which were already
isolated. Everything Calvin surmised from there on seemed to
link up logically. However, he neglected energy balances. Many
experiments with similar results seemed to show that 8 photons
were required for each CO2 molecule in the air in
order that the plant could synthesize organic compounds. But
what plant? Conclusions true for a particular plant were
incorrectly extrapolated to other plants. For these, the
Calvin cycle required a much higher number of photons.
Consequently this cycle, adopted with enthusiasm by a majority
of the people, was the subject of justified objections. The
cycle was modified several times and Calvins name is now
followed by the names of the main researchers who added to it.

Despite all these additions, some organic
molecules formed by photosynthesis in certain plants could not
be explained by the Calvin cycle. Following a very human and
common tendency, studies of photosynthesis had been conducted
mainly on a single plant, spinach, which supplies green
material in large quantities and almost all the time. It was a
fashionable plant. The results were extrapolated to every
plant. There was one photosynthesis mechanism. It was
concluded that chlorophyll (a and b in particular) was the
same everywhere, and consequently that chemical reactions had
to be identical in every case.

Experience contradicted this simplification. It
was observed that the Calvin cycle broadly applied to almost
all dicotyledons, but that it did not apply at all to plants
as common as graminaceae, such as corn, sorghum and sugar
cane, all of which are monocotyledons. These plants fix the CO2
of the air at a much higher rate. They need less organic
fcrtilizer and they need less humus, because their
carbonaceous components are derived out of the air in larger
proportion. This is also the case for weeds.

In the Calvin cycle, the CO2 from the
air attaches to ribulose 1-5 diphosphate molecules. Each
resulting molecule decomposes into two 3-phosphoglyceric acid
molecules. On the other hand, in the Hatch and Slack cycle,
the CO2 is fixed by carboxylation of the
phosphophenolpyruvate with formation of oxaloacetic acid. This
acid reacts with C2 or C5 molecules to
form pyruvic and phosphoglyceric acides.

This big difference between the two cycles can
be presented in another way. In th Calvin cycle, the compounds
formed from the CO2 in the air are primarily
compounds with 3 atoms of carbon, such as glycerol-3-hosphate.
In the Hatch and Slack cycle, C4 compounds are
synthesized, such as oxaloacetate.

In other words, dicotyledons fix 3 carbon atoms
and monocotyledons 4 carbon atoms. This explains the better
yield for the latter. Synthesized enzymes are also different.
There is more in the Hatch and Slack cycle than in the Calvin
cycle. Some dicotyledons growing on salty lands follow the
Hatch and Slack cycle. This would be due to a still unknown
property of Na, tentatively attributed by some people to a
transmutation of Na. These plants can be used to desalt a
soil.

The Calvin cycle is the cycle in C3
and the Hatch and Slack cycle is the cycle in C4.
Consequently, the latte produces more carbohydrates and more
dry material. It requires only half as much water and more dry
material. It requires only half as much water. This is the
reason why these plants can grow well in fairly dry climates,
as is the case with corn, sorghum, etc.

There is another important difference. In the C3
cycle, 40-50% of the atmospheric CO2 initially
fixed is returned to the atmosphere by photorespiration. This
could explain why in a closed chamber the atmosphere can still
contain some CO2, although the incoming air has
previously bubble through a solution of caustic soda to fix
any incoming CO2. The remaining CO2
decreases slowly and asymptotically. The plant wilts and dies
slowly. On the other hand, in the C4 cycle very little carbon
is returned to the atmosphere. Almost all the carbon which is
fixed is retained. Carbohydrates are formed more quickly.
Grain plants, such as cereal plants, lack CO2 much
sooner than most other monocotyledons when they are grown in a
closed atmosphere, fed through a caustic acid solution. Their
chlorophyll deficiency can be soon observed. At least, this is
my interpretation.

**(f) Isotopes ~**

One should also observe in passing another
phenomenon. Monocotyledons and dicotyledons are not only the
seat of different chemical reactions, but they also have
different physical behaviors. They fix stable carbon, oxygen
and hydrogen isotopes differently when they come from CO2
and from water. In the sugar beet (a dicotyledon), saccharose
does not have the same isotopic composition as the saccharose
in sugar cane (a monocot). This question was studied recently
with the greatest care. Its implication is not only
scientific, but also economic. The selling price in sugar cane
is much higher than the selling price in beet sugar. Fraud is
possible. For the chemists in charge of the analyses,
saccharose is saccharose; its formula is the same. It is
impossible to determine its origin after it has been purified.
But Nature does not dabble only in chemistry, it also dabbles
in physics. C13/C12, O18/O16,
H2/H1 ratio variations are high enough
to be detected with mass spectrometry. Customs and the Agency
for the Repression of Fraud are now equipped to check sugar to
determine its area of origin. They use the same techniques
with other compounds and other plants.

The treaties I know on photosynthesis are all
silent on this point. Many other points are still unknown.
Understanding of detailed reactions in chlorophyll still
escape us. We only know some intermediary steps, and the
molecular structures resulting from the combined action of
photomorphogenesis and photosynthesis. We still do not know
what happens inside the chlorophyll molecule at the atomic
level. This molecule includes approximately 150 atoms grouped
around a nucleus or heart of porphyrin. This porphyrin is
formed around a magnesium atom linked to 4 nitrogen atoms.
What happens at this level? Though magnesium is at
chlorophylls core, it is never included in the formulas
proposed by agronomists. Furthermore, it is assumed that
chlorophyll preexists, but one does not known how Nature
reproduces it. As the pant develops, the number of leaves
increases, leaves grow and chlorophyll forms. Magnesium is a
transition metal element, Does it act only as an electron
carrier as iron in hemoglobin, copper in the hemocyanin of the
shellfish, vanadium in ascidiae, etc.? There again we do not
know the internal process generated by this central atom; we
do not even know the process generated by porphyrin, which is
built around this atom.

**(g) Conclusions ~**

Photosynthesis cannot be totally explained by
chemical, hence molecular, phenomena, which have not been
completely explored. There are indeed phenomena at the atomic
level, such as variations in isotopic composition. However, we
should consider the possibility of subatomic phenomena. These
may be direct or indirect mechanism. I am inclined to say
indirect and they work through the unquestionable and
selective action of specific enzymes, growth hormones and
other hormones. These compounds may contribute to the
transmutations which were clearly shown in the course of the
experiments. Nothing is simple. Results obtained with one
plant cannot be extrapolated and applied to all plants.
Failure will result if this point is not kept in mind. Each
experiment should be performed according to a well defined
procedure. In this field innovation may lead to poor results.
Even a simple question of lighting, of inappropriate spectrum,
may make the difference between positive and negative results.
This is essentially the point I am trying to make.

**(2) Photosynthesis (Limited to Traditional
Aspects) ~**

In most treatises the study of photosynthesis is
based on the research based on spinach. This produces
unwarranted generalizations.

In one kilogram of spinach leaves there are
approximately 500 million chloroplasts. 60% of the weight of
the proteins contained in the leaves are located in these
small organs which are concentrated in the cytoplasm of the
leaves.

These chloroplasts are 7-8 micrometer long and
2-3 micrometers thick. They are filled with a lumpy liquid,
the stroma, which is surrounded by a double envelope. One of
these constitutes a membrane network, the thylakoids.
Thylakoids are vesicles filled with a liquid composed 80% of
glycolipids and sulfolipids. Their envelopes contain very
little phospholipids, but they contain chlorophylls (150
micrograms of proteins and 30 micrograms of pigments such as
carotenoids). Nearly 50% of the proteins contained in the
chloroplast are located in the thylakoid envelopes.
Cytochromes and plastocyanin were found in them; they are
proteins which can give or receive electrons according to
their environoment. The nature of the constituents inside the
thylakoids seems to be totally unknown as of 1980.

The stroma is rich in soluble proteins (about
0.4 gr/ml of stroma). It contains about 50% of the proteins in
the chloroplast. The stroma contains the DNA and RNA which
synthesize  some proteins in the chloroplast. The lumpy
aspect of the stroma, revealed by the electron microscope, is
mainly attributed to ribosomes. The surface area for the
external chloroplast envelope amounts to about 500 cm2
for one gram of leaf. The envelope contains only 1-2% of the
proteins in the chloroplast. To this day, none of these
proteins have been isolated it seems. Chloroplasts transform
ADP in ATP under the effect of light and in the presence of
electron acceptors.

The knowledge of photosynthesis progressed after
intact chloroplasts were obtained in 1965. They simultaneously
give some oxygen and fixed CO2 in a 1/1 ratio in
the presence of light. However, chloroplast separation
techniques were only applied to a very few vegetal species.
Experiments were primarily performed with spinach. Test
preparation was perfected for this plant. Its green material
can be harvest all year round. Consequently, it was the
subject of 70% of the research. This led many researchers to
extrapolate their results to other species. This is a mistake.
It was observed in some green plants, such as corn and sugar
cane, that some intermediary steps were different from the
steps in spinach reactions. This showed that the
photosynthesis for spinach, a dicotyledon, did not apply to
these monocotyledons.

When thylakoids are exposed are exposed to
light, electrons are transferred between water and a final
acceptor, of still unknown structure, designated as X protein.
Walter Redox potential for the final acceptor, Eo
= 0.1 V. Therefore, it is necessary to bring energy in, to
operate the transfer. The energy is brought by light photons.
This energy transfer is coupled with an ADP phosphorylation
into ATP; this constitutes the energy storage mechanism. Light
energy is collected inside the thylakoid membrane by two
antennas each belonging to a different photosystem. These
antennas comprise a system of proteins and pigments
(chlorphylls and carotenoids) which absorb light energy and
transmit it, by resonance, to the a-chlorophyll which is
different in each photosystem. His chlorophyll is oxidized.
One of its electrons is transferred to an acceptor. The
transfer creates a high potential gradient, 0.8 V for one
photosystem and 1 V for the other. For the first one, water is
the electron donor, but to this day the acceptor is unknown.
It is designated as the protein.

A magnesium base proteins intervenes during this
reaction. Water is oxidized, giving protons and molecular
oxygen (schematically: H2O + O = H2 + O2).
The detailed mechanism of this reaction is still the subject
of current studies. It is now generally accepted that oxygen
is dissociated from water and not from CO2, as it
was initially believed. In the other photosystems, the
electron acceptor (X) is a protein which includes iron and
sulfur atoms. Fe and S have a very low Redox potential. The
two systems are connected by a chain of carriers which is
little understood.

Q molecule electrons are successively
transferred to quinines, to various cytochromns and then
finally to plastocyanin, in which the electron donor is a blue
protein containing copper.

Electrons are transferred from X proteins to
ferroxoxin, which is a very small protein (molecular weight of
the order of 12,000) of a low Redox potential. Eo
= 0.32 C, containing Fe and S). Ferrodoxin contains iron and
sulfur. Ferroxin can transfer its electrons to various
molecules such as nicotinamide-adenine-dinucleotide-phosphate,
NADP. It can also transfer them to a nitrite based
flavoprotein. This transfer produces NH ions and electrons can
be transferred to oxygen with production of superoxide
radicals.

In this case the overall balance may be
summarized by the following relation:

H2O + NADP >> NADPH2
+ 1/2 O2

The NADP is reduced and the oxygen probably
comes from the water. The primary effect of this transfer of
electrons is the production of the highly reducing NADPH2
molecule; oxygen is only a by-product, so to speak.

We shall note that magnesium, the central atom
of the chloroplast molecule, does not appear in these
formulae. Its function has not yet been established. Many
unknowns remain. Isnt such research purely speculative? Many
teams of researchers throughout the world are attempting a
direct transfer of electrons to a final acceptor by the
channel of ferrodoxin coupled to hydrogenase. Hydrogenase is
an enzyme extracted from bacteria or from molecular algae,
through reactions producing molecular hydrogen. Hydrogen is a
non-polluting source of energy. In nature, the
ferrodoxin-hydrogenase pairing is observed among many bacteria
produce a reaction similar to the above except that they dont
free any oxygen. The thalla which live in symbiosis in the
blue algae, does produce oxygen.

The production of hydrogen results in a pH
modification on both sides of the thylakoid membrane.
Plastoquinones, carriers of both protons and electrons, are
reduced by Q molecules on the external face of the thylakoids
and they capture protons from the stroma. However, the
plastoquinones, oxidized by the cytochrome near the thylakoids
internal envelope, also discharge some protons in the stroma.
The protons formed during the oxidation of water contribute
also to reinforce the pH gradient in the presence of light.
Balance is due to the phosphorylation of ADP into ATP based on
the formula proposed by the Englishman Mitchell:

ADP3- + H+ = HPO42-
>> ATP4- + H2O

The detailed process of this schematic reaction
is unknown.

ADP and NADPH2 molecules bring the
necessary energy and the electrons to the stroma to fix the
carbon dioxide from the air and to synthesize carbohydrates.
37 ATP molecules and 24 NADPH2 molecules are
required for the synthesis of one saccharose molecule from H2O
and CO2. In plant species of a type similar to
spinach, the stroma inside the chloroplasts produces C3
molecules primarily (phosphorylated C5-oses:
glyceraldehydes-3-phosphate or its isomer,
dihydroxy-acetone-phosphate). This is a complex process
realized in three steps. A C5 sugar is first
decomposes in two 3-phosphateglyceride acid molecules. It is
during this step that the CO2 from the air is
integrated into organic molecules. One CO2 molecule
and one H2O molecule are consumed. This reaction is
catalyzed by an enzyme of large molecular weight (500,000). It
is a complex enzyme composed of 8 large units and 3 small
subunits. The second step is subdivided into two sub-steps and
the third step corresponds to regeneration. This series of
steps is known as the Calvin cycle or now, as the BBC for
Benson, Bassham and Calvin.

Phosphorylated oses are produced in C6
(fructose), in C4, C7, and finally in C5
(ribulose). In 1973 Held showed that the pH of the stroma
increased in the presence of light. The stroma loses protons
to the inside space of the thyladoids until a balance is
reached. In darkness it is the opposite. Enzyme activity is
controlled by these pH variations.

Beet sugar and spinach leaves behave similarly.
Both plants are dicots. Each square meter of beet leaves feeds
about 130 mg/min of glucids in the veins of the leaves 
from which the glucids move to the roots for storage. The
mechanism controlling the subsequent transformations of the
3-phosphates glyceraldehydes, after they reach the cytoplasm,
is not known. Those which are not sent to the cytoplasm and
those in the stroma, are transformed into starch which is a
high saccharose polymer.

Contrary to saccharose, starch is not
phosphorylated. There is a biological limit to the yield of
the photosynthesis process. During the respiration phase,
plants controlled by the BBC cycle waste a large part of the
carbon integrated during the photosynthesis phase. It is
estimated that these plants use only 1% of the 5.1020
kilocalories received each year from the sun. This
consideration underlines the economic importance of the next
cycle.

**(3) Photosynthesis Cycle of Hatch and Slack ~**

The photosynthesis cycle of Calvin is well
known. It is the classic cycle in all published works, because
it was most widely studied. In fact, a study of the C13/C12
isotopic ratio (research of 1968 by Bender) showed that it
could vary by 5-15% and even more according to the
photosynthesis cycle of the vegetal species. The study showed
that this result was independent of the composition of the
living medium for the culture and that it did not vary with
time. The variations in the ratio could only be attributed to
the physiology of the plant under the control of its specific
enzymes. The emphasis was placed on the ratio between the two
stable carbon isotopes in corn, as the chlorophyll metabolism
seems to fix proportionally less C13 from the
atmosphere.

Research on photosynthesis was first made with
dicots because there was a convenient source of supply of raw
material. The research extended to monocots such as corn.
Sugar cane was included in order to stop fraud in sugar. Cane
sugar contains more C13 than beet sugar. As
previously mentioned, the Calvin cycle combines the CO2
from the air with ribose-1.5-diphosphate in beet sugar. The
resulting molecule decomposes into two 3-phosphoglyceric acid
molecules. As early as 1966, Hatch and Slack discovered
another cycle in monocots. In that cycle, they showed that the
CO2 from the air was fixed by carboxylation of the
phosphenol-pyruvate and formed oxaloacetic acid. This acid
combines with C2 or C5 molecules to form pyruvic and
phosphoglyceric acids. In France, J. Bricout and others
observed that the C13/C12 isotopic
ratios were significantly different for beet and cane sugars.
The decrease in C13 is of the order of 1.1%,
compared to its concentration in the CO2 control,
for cane sugar. The decrease is 2.5% for beet sugar.

We see the advantages of cultivating monocots
rather than dicots. They derive more carbon dioxide from the
atmosphere and require less organic feed. Many weeds have the
same property and they grow even without fertilizer.

**FIGURE 13 ~ [Missing]**

**[FIGURE 14](fig14.gif)
~ Values of Ca**

---

**Chapter 5**

**The Devils Advocate**

When I published my first works I had problems
with chemists for whom theory precedes facts. For them,
nothing is lost and nothing is created. This is true in
chemistry. To many biochemists, life is only chemistry, and
chemistry is the supreme science which explains everything,
even the most abstract: will power, feelings, etc.

With a wealth of experiments I showed that
chemical balances between elements in and elements and
elements out were not always null. I was astounded by the
naivete and the lack of realism of these biochemists. Their
final argument was that a balance which was not null could not
only be attributed to incomplete analyses. They claimed that
some elements were surely hidden in a form which could not be
detected by the analyses as performed. They did not realize
that they only confessed their incapacity to perform correct
chemical analyses. Chemists, even those who boast of being
professors in our universities, could not be trusted.

Confronted with such common attributes, I just
shrugged my shoulders. To avoid useless polemics, I decided to
stop referring to chemical analyses and to use modern
techniques of physical analysis such as flame spectroscopy for
J, atomic absorption spectroscopy for Ca, etc. At the
beginning of my research, physical techniques to
quantitatively measure specific anions, such as S, P and N,
had not been developed. The same is still true 20 years late.
His is why my studies, and those of researchers who wanted to
duplicate them, were limited to the study of balances for a
few important cations by various physical techniques.

In France a university professor, who was a
high-ranking Rationalist wrote in a publication that I was
wrong. He was director of the biological chemistry laboratory
in his university. Rationalism was a philosophy publicized by
Robespierre, pope of the Goddess Reason. This professor had
decided to duplicate, as he said, one of my experiments. In
fact his experiment differed extensively from mine. A summary
of his study was included on pages 88-91 of my book, now out
of print, *Preuves Relatives a lExistence de
Transmutations Biologiques*, published by Maloine in
1968. The essential argument was reproduced on pages 212-213
in my book of 1975, *Preuves en Biologie de Transmutations
de Faible Energie*, which is still being reprinted. I
will not say more on the obvious bad faith and the exaggerated
cynicism of some sectarian objectors. Far be it from me to
place all Rationalists under one label. There are exceptions
among them as there are exceptions everywhere. I learned that
several distinguished scientists among them protested against
the attitude of this learned master.

However, he was not the only one to think in
this way. I mentioned the case of the hidden iodine produced
by some algae, which cannot be measured in a certain vegetal
state, but can be measured in another state. This showed
indeed that some experiments were deficient. To point at the
errors was not sufficient. To disdainfully reject gratuitous
affirmations was not the solution to definitively eradicate
affirmations was not the solution to credulous and
unscientific minds of too many biochemists. Figures were
necessary. In the book mentioned before, dating from 1968, on
p. 158-167, I had indeed given some precise information.
However, it concerned phosphorus variations during the
germination of lentils. Undoubtedly this escaped various
phytobiologists. I noted in a publication, Revue de Biologie,
that a professor of botany was still imbued with 19th century
dogma in 1980. Criticizing the data presented by Zundel on the
increase in Ca during the germination of oats, she writes, "If
the ashes are dissolved in hot HCl, the acid cannot dissolve
Ca which is in the form of sulfates and phosphates. An
underestimation of the total quantity of Ca in the caryopses
could result, whereas the Ca contained in the seedlings, and
which can be oxidized, would be counted in its totality. This
could explain the increase in Ca which was noted". General
statements are made without regard for the precise
experimental data, which are not even mentioned. In the
previous paragraph, she wrote: "In caryopses, Ca is partially
found in phytins (inositol hexaphosphate of Ca and Mg) in
aleurone granules, and partially as insoluble phosphate and
sulfate. In seedlings, Ca is found mainly as pectate, which is
transformed in oxide by combustion".

But what are these pectates? "Combustions"?
Arguments, but no figures! The "partially" is meaningless.
Which part? Which proportion? I will quote figures later. So
much for the questionable, and even partially wrong. Opinion
expressed by this university professor. Before presenting my
figures, I believe I should say a few words presenting my
figures, I believe I should say a few words about phosphorus
which is not part of this work.

---

**Chapter 6**

**Problems Related To Phosphorus,
Complexity Of Phytoanalyses**

Phosphorus and calcium in living matter are
closely related. They have  been studied for a long time.
I dedicated a chapter of my 1975 book to Vauquelins studies
on the balance of the calcium ingested by a hen. Calcium is
found as carbohydrates and sulfates in oats, in the egg laid,
and in droppings. Vauquelin mentioned chemical analysis
procedures to measure the Ca linked to P and to the carbonate.
This is not a new problem.

In my book of 1968 I presented some detailed
information on the studies related to form changes of P during
seed germination. It came from a doctoral thesis written in
1935 by a pharmacist, Yves Colin, after a five-year study. I
own a printed copy of this document in which 84 pages are
dedicated to "Technical Research on the Separation and the
measurement of Primary Phosphorus Elements in Seeds". Colin
presented some data on wheat and on sunflowers, but his
research was primarily on lentils. P and Ca contents are the
same in lentils and in oats. However, there are marked
differences in the nature of P compounds in different vegetal
species, so that the analytical procedure varies from species
to species. I did not include in my 1975 book the chapter
which dealt with this matter in my book of 1978 which is now
out of print. One can refer to Y. Colins thesis in university
libraries. It will show precisely how wrong and biased were
the statements expressed by the professor of botany mentioned
previously, statements unsupported by quantified data.

Good chemists know that P compounds are not
soluble in any old solvent. Solvents must be selected. Care
must be brought to the sequence of the reactions. A reaction
can stop the sequence by fixing P in a compound which is then
totally insoluble in the following reaction and it will then
resist all attempts to measure it.

In plants, P is found in phosphoric ester such
as true phosphoro-lipids. Among the photo-lipids are found
lecithins, but mostly they are glycerol-phosphoric acid
derivatives. One also finds P in phosphoric acid esters of
sugars, diphosphoric hexose monophosphoric ester,
momophosphoric polyoses, etc. During the last decade of the
19th century and the beginning of the 20th century many
studies dealt with P compounds and their quantitative
variations in germinating pants. Phospo-lipids and
phospho-amino-lipids were studied first, then the nucleic
acids which incorporate large quantities of organic P were
studied. After hydrolysis, they release o-phosphoric acid.
Nucleic acids differ according to the plant; some information
on this subject may be found in my book of 1962. These studies
led researchers to look for various ways to separate these
compounds. For a given solvent, results may vary according to
acid concentration and temperature. My former colleague at the
Conseil dHygience in Paris, Gabriel Bertrand, was convinced
that transmutations occurred in the metabolism of living
matter. He also showed me that P contents in ashes and in the
dry material were different. Differences were of the order of
10% if reactions, on material dried at 100 deg C, were performed
in a wet medium. At 200 C a loss of P was observed: this was
mainly due to the fusion of of alkaline phosphates. Fusion
produced a slag surrounding the particles of organic
phosphorus which could not be decomposed by acids. Generally,
these phospo-lipids and phospho-nucleic compounds have no
close relation with Ca; their study may be ignored in research
on Ca.

On the other hand, phosphoro-proteids, which are
not water-soluble, but are alkali soluble, are very important
in fresh plants, though they are not widely found in animal
tissues. Phytin was discovered during the 19th century. It is
a hexaphosphoric ester of inositol, or more exactly it is a Ca
and Mg salt of this ester. In 1903, Posternak established that
organic P accounted for 22% of the phytin, Ca for 12% and Mg
for 1.5%. therefore there are large quantities of Ca. Inositol
is a polyaclohol widely distributed throughout plants. In
grain plants it accounts for approximately 50% of the total P
and over 70% in sunflowers. In his thesis, Colin describes the
techniques which were perfected since the beginning of this
century. These techniques were primarily developed by
Javillier around 1930; we both sat together on the Conseil
dHygience. He modified the analytical technique developed by
Copeau in 1927. Mineralization comes about through a mixture
of sulfuric and nitric acids (to which Baranger added some
concentrated hydrogen peroxide). Phospho-amino-lipids are
first extracted. Some per-compounds are explosive and must be
handled with care. One must follow carefully the instructions
given by the specialists in this type of research. For our
study of Ca, the important analyses concern acid-soluble P and
then mineral P. To separate phytinic P from total P, Colin had
to develop a technique derived from Javilliers procedure.
This was because the P in the seeds of cereal plants differ
markedly from the nucleic acid formed in lentils. The presence
of iron modifies the sequence of the reactions and requires
the use of hydrochloric acid.

In 100 grams of dry powder of lentil seeds or of
oats, there are 300-400 mg of P in total. 50% of this total is
in phytin; a little over 10% is lipid P and a similar amount
is nucleic P. The ratio of the last two kinds varies little
during germination. As they are not linked to the production
of ca, we will not show any data for them. Colin quotes
results for batches of 400 lentils picked every third day
after the lentils were prepared for germination. Here are the
weights in mg for each batch:

*P (Phytin) ~ P (Mineral) ~ P (Total)*   
Before Germination: 50.63 ~ 18.30 ~ 92.00   
After 3 days: 38.31 ~ 30.84 ~ 93.65   
After 6 days: 12.64 ~ 54.61 ~ 90.00   
After 9 days: 0 ~ 62.30 ~ 87

Other analyses were made after 12 days and after
33 days. We will not discuss the results here. The main point
is that the P in phytin decreased significantly after 3 days
and that it decreased by approximately 3/4 after 6 days. It is
around the 4th and 5th days that the rapid transformation of
phytin P into mineral P takes off. There is also a progressive
decrease in total P, which was confirmed by other studies on
soybeans and on vetch and oats. I shall come back to this
point. It is remarkable that all the organic P in the phytin
disappeared after 9 days, as it was transformed into mineral
P.

In the seed, mineral phosphates of Ca and Mg
amount to about one-half of the P contained in phytin. The Mg
is negligible. In the plant there is no more phytin after 9
days and mineral P is a little over 3 times greater than in
the seed. Therefore, if the mineral phosphate in the plant is
neglected by the experimenter because it is not soluble in
HCl, the amount the amount of Ca in the plant is
underestimated. This is the opposite of what was stated by the
professor of botany mentioned in the previous chapter.

---

**Chapter 7**

**How To Correctly Duplicate A Typical
Experiment On Biological Transmutations**

When one wants to check a phenomenon, witnessed
by another person, it is not right to give an opinion on the
validity of the phenomenon unless the procedure used to
establish it is strictly followed. If one parameter is
different and if the authors conclusions are not confirmed,
it is right to first ask of the failure of the experiment is
not due to the change in the procedure and to the neglect of
some essential points.

In other words, the verification of an
experiment requires the exact duplication of the experimental
conditions set by the researcher who established the existence
of the phenomenon. It is legitimate to innovate only after
this has been done.

Too often operators attempting to duplicate
experiments modify the procedure described by the inventor.
They do so for several reasons.

In the goal they pursue they underestimate the
importance of some points of an experiment, which is new to
them. This may be due to ignorance or to professional bias.
Some extremely complex fields of research require a good
knowledge of nuclear physics and chemistry, and an outstanding
knowledge of biology. This is the case for biological
transmutations which are biophysical phenomena which can be
detected by wet chemical analysis or physical chemical
analysis.

**(1) Study of the Calcium Variation in
Cultivated Oats ~**

We will look at a study performed by a team,
composed of a physicist and a phytobiologist, in an American
university.

They wanted to check if there was an effective
increase in Ca and an effective decrease in K during
germination as compared to the initial amounts in the seeds.
Germination took place in ultra-pure water. No Ca could be
derived from the water nor from the bottles used for the
experiment. This was checked prior to the beginning of the
experiment.

Theoretically, according to classic rules, the
Ca balance, as well as the K balance, should not change,
because "nothing is lost, nothing is created". This is true in
chemistry. However, this does not apply to some specific
biological processes involving not only chemical reactions but
also prior to them, phenomena ruled by nuclear physics.
Chemistry deals with phenomena involving electrons, and in
general only the outer shell electrons of the atom.
Electromagnetic energies, it would seem, cannot cause any
transmutations. There are various reasons for this, but they
will not be discussed here. These transmutations can happen
under the effect of strong or weak interactions as it will be
explained in Part II of this book.

After performing only one experiment, these
American scientists concluded that my observations were in
error. For the K/Ca ratio, they found an average value of 4.5
for the seeds and only 1.5 for the plants after germination
and after too short a cultivation period, in my judgment. From
the outset, they should have attributed K/Ca variations either
to a decrease in K, or to an increase in Ca, or to
simultaneous variations of K and Ca. Lets more closely
examine the reasons which led to their conclusions.

They analyzed three aliquot parts of a batch of
seeds and of plants grown from "identical" seeds. I will not
cast any judgment on this technique, which, it seems, was used
for the first time in this case. It might be a mistake to try
a new technique in this instance. Though I know of so many
scientists who are prisoners of their habits and sometimes of
their equipment and who are incapable of admitting that they
are wrong. To them, their technique is the best; they adopted
it once and for all. This is a conceited attitude common to
too many scientists. It is a mistake. Various techniques
should be used for cross-checking.

For example, I observed some unacceptable
discrepancies in analytical data obtained by complexometry
techniques for Ca. The nature of the complexing agent must be
adapted to the Mg/Ca ratio in the solution analyzed. In spite
of a double precipitation, the same is true for analyses by
means of oxalate salts. Specific techniques are legitimate in
some cases and not in others. In the same way, precipitations
must be performed in the right sequence. Otherwise a
particular molecule may be made insoluble to the detriment of
subsequent reactions. Unfortunately knowing and remembering
this point is not enough. This is the case in experiments
involving biological transmutations, when the outcome of a
first transmutation is unknown in advance. A technique may be
valid for the control and not for the end product due to the
modifications caused by the transmutation in the ratios
between some elements. Two steps of an experiment may not
always be cross-checked with the same technique if one wants
to reach the right conclusions.

Of course I do not object to chemical analyses,
but the point emphasized above should always be kept in mind.
I always used the atomic absorption spectrometry technique for
the analysis of Ca (or Mg, Fe, etc.) to obviate the
uncertainties presented by some chemical techniques and to
prevent (often ungenerous) objections by experimenters imbued
by their own technique. Uncertainties in chemical procedure
can generally be cleared, once the experiment is mastered and
once its results have become reproducible. This requires that
the parameters of the experiment be maintained constant.
Zundel used a chemical technique, developed by Prof Charlot,
for the analysis of Ca in oat seeds and plants. The material
is heated to 950 deg C to avoid the formation of carbonates, and
to insure that all Ca in the final reaction is in the form of
CaO. The CaO is weighed to 1/10 mg for each batch. The amount
of Ca is then computed. With this technique, Zundel obtained
fairly constant figures, though they were always slightly
higher than those given by atomic absorption
spectrophotometry. This was true for both seeds and plant so
that the ratios between the Ca contents in the seed and in the
plant are independent of the analytical techniques. Variations
in the absolute value of Ca may be ascribed to various causes:
calibration differences in the physical technique or the
presence of contaminants not precipitated previously in the
chemical analysis. Despite these factors, comparative results
obtained by these two techniques often show little difference.
Balances are usually reproducible to a few percentage points
with each technique. Too many physicists, even chemists and
biologists tend to ignore, underestimate or neglect
differences from one biological batch to the next. Among seed
as among animals, there are vigorous subjects and there are
weaker subjects. At times differences in the nature of the
subject can be detected chemically or by analysis of the
isotopes. The isotopic composition of an element does not
necessarily translate to an organic compound of the same
element. The chemical formula for its three main components,
H, O and C, are not the same for cane sugar as for beet sugar.
In biology calculations should not be based on standard atomic
masses, which are average values as stated in our books.
Although they are precisely defined, they are only arbitrarily
selected standard values. In reality there is no such thing as
isotopic selectivity.

This is why, in my studies, I decided to accept
only variations greater than 5% in average values for the
elements considered. It is understood that the number of
analyses performed must be sufficient to yield statistically
valid averages.

Several cross-checks by neutron activation
performed in authorized nuclear physics laboratories showed
that the technique was also valid for Ca. Magnitudes were
approximately the same as those found by atomic absorption
spectrophotometry. With a minimum of 5 readings, measurement
dispersion was smaller than 4%. Neutron activation, which is
non-destructive, should not be used to first test a seed and
then the palnt grown from this seed. I was able to establish
that the plants germinating factors were altered by this
technique. The plant metabolism is modified and transmutation,
which are produced by enzymes, are slowed down. (please refer
to my book of 1975, p. 233).

From the beginning of my research 20 years ago,
I abandoned chemical techniques for K analysis. Prof Baranger
of Ecole Polytechnique in Paris, a chemical analysis
specialist, finally abandoned the chemical analysis of K after
he had obtained questionable results for several years.
Zundel, a chemical engineering graduate from the Zurich
Polytechnicum, who supervised a chemical analysis laboratory,
also abandoned the chemical analysis of K from the start of
his studies on transmutation during the germination of oats.
We used emission flame spectrometry despite the inherent
difficulties in reducing measurement discrepancies from one
sample to the next.

The flame spectrometer is still an instrument
which is difficult to set for good reproducibility. It is now
used by everybody, as there is no better instrument for the
various purposes. Many readings are required with this
instrument to get statistically valid results. There are some
reservations on the various statistical methods prevailing in
different countries as all these methods are based on
arbitrary postulates.

It is impossible to obtain statistically valid
conclusions on biological samples from a small number of
analyses performed on aliquot parts, which are sometimes too
light in weight to start with. Usually we make 5 to 10
readings on a given sample. At times we made up to 50 tests.
Baranger tested up to 300 and even 400 samples one by one. On
the other hand, it seems that only three analyses were
performed in the USA. The results obtained were so scattered
that they were statistically invalid. Nevertheless, it was the
basis for the negative conclusions expressed by the scientists
who performed the experiment even though the average data
showed a large variation of the K/Ca ratio.

**(2) Biological Conditions ~**

Ca and K variations during the germination of
oats observed in the USA were different in absolute value from
those we had customarily observed during tens of congruent
experiments. These experiments included hundreds of analyses
performed on thousands of plants and tens of thousands of
seeds. This consideration led us to carefully examine the
content of the report written by these scientists.

It showed us also that they underestimated or
ignored some biological factors.

We recommended oats for the study of Ca, as this
plant was extensively studied and it showed clear results. The
increase in Ca is considerable, often greater than 100%,
independently of the batch or the species, when the seed is
germinated in twice-distilled water with an acid pH (5.6-5.8).
The oat plant grows on acid soils, hence it is clearly a
calcifuge. The seed contains little Ca, an element necessary
for the first reactions for the germination process. Ca is
required until growth hormones are synthesized. After 8-10
days the total Ca content of the seed and the seedling begins
to increase very rapidly at the expense of K, although no Ca
can come from the outside. The seed is rich in K as its K/Ca
ratio is approximately 4.5 and varies little for different
species. It constitutes the reserve for the growth of the
plant. This ratio decreases the reserve for the growth of the
plant. This ratio decreases to about 1.8 over 3-4 weeks and
then declines asymptotically to 1.5, the minimum value reached
after 6 weeks. After this time the K reserves are too low to
compensate for Ca and the pant starts to wilt. We do not know
if the pH was  measured in the American study. The pH is
not mentioned in the text we received. It is not critical in
this particular case, because the water pH was certainly acid.

It seems to me that unsatisfactory cultivation
conditions are the primary reason why no statistically valid
increase in Ca was found. A researcher should not try to
innovate while exploring entirely new grounds. He should
follow the instructions of the people who have long experience
with the phenomenon and who have mastered this phenomenon only
after extensive research.

My attention was drawn to a short sentence
mentioning that the germination was performed under artificial
fluorescent lighting with a lamp of the warm white type. As I
have studied fluorescent lighting over 20 years, I jumped. The
warm white lamp gives a spectrum which appears close to the
solar spectrum to our eye. It enables agronomists to easily
detect color changes in the seedlings. However, such lamps
should not be used for photosynthesis. Plants and the human
eye have very different sensitivities to light spectra.

In the beginning our studies were only made
under sunlight, to approximate natural conditions for the
plant as closely as possible and to prevent the introduction
of an additional unknown. After a few years, various
considerations forced us to use artificial lighting. We needed
to experiment at various times and in various seasons at
poorly lit locations. Some varieties of oats, often called
winter oats, are sown in fall, others at the beginning of
spring. It took years of research and the help of discharge
lamp specialists to select the right lamps. Only these lamps
could radiate the short wavelengths in the blue, violet and UV
which are so important for photosynthesis. Wavelengths in the
red, which carry heat, are also well represented in the
spectrum of these lamps. On the other hand these lamps radiate
very little in the yellow, the band of maximum sensitivity for
our eye.

This research led to the development of lamps
with spectra well tailored to photosynthesis. For visual
observation, lamps of the warm white type or equivalent are
needed. However, they are only used intermittently and they
cannot replace solar light in any way for photosynthesis.

The phytolamps used were usually rated at 250
watts and sometimes at 400 watts. This was a high but
necessary power rating. These lamps radiate a great deal of
heat and they must be located outside the cultivation
chambers. The chambers are not made of glass, but of
metacrylate. For supply considerations Altuglas rather than
Plexiglass was used. Metacrylate, as glass, absorbs some UV
wavelengths. The bands filtered change according to the
material. Therefore, plants cultivate under glass or
metacrylate are affected differently by light photons than
plants grown in the open under sunlight. For this reason we
placed a small lamp inside the chamber rated at a few watts,
which radiated complementary wavelengths in the near UV. With
this lighting, we obtained plants as vigorous and as rich in
Ca as plants grown under direct, unfiltered sunlight.

The American researchers stated that their
seedlings were more yellow (chlorosis) and more flaccid than
those normally grown in sunlight. They did not mention if they
had considered the possibility of deficiencies in
photosynthesis. Another effect of this process is easily
checked. Under this mechanism, the plant produces some dry
material from various synthesized carbohydrate compounds
(glucids, lipids, parotids, etc.). Lignin, composed of the
resulting celluloses (hemicellulose, etc.) contributes to
plant system rigidity. The stems of the plants grown by the
Americans remained flaccid and bent. This was a sure sign of
deficient photosynthesis. In order to form carbohydrates, the
plant takes its carbon from the carbon dioxide in the air and
its H and O from the water absorbed by its roots. A
satisfactory photosynthesis is therefore indispensable to
plant metabolism and for the synthesis of essential growth
enzymes; it is absolutely necessary for the good health of the
plant. An enzyme linked to oxidizing phosphorylation, and
created at the internal surface of the mitochondria inside the
envelope, is responsible for the formation of Ca from K with
Mg as a catalyst. The enzyme active in this reaction is
derived from ATP chelated with Mg (Mg-ATPase). This is a point
I discussed in my books. Another point was presented by S.
Goldfein in a report written for and published by the
scientific section of the US Amy in Fort Belvoir, CA in 1978.
Without the normal activity of this enzyme, there is a
deficient plant metabolism and a transmutation which is too
weak to yield significant amounts of Ca. This happened in the
experiment performed in the USA. The seedlings were weak and
stunted. The stems were only a few centimeters long. During
the same growing period, we obtained firm and erect stems
20-20 cm long. We also obtained a much greater weight for the
dry material, and even for the ashes, than for the seeds. A
poor photosynthetic action prevents the formation of
carbohydrates. Furthermore, the weights for the dry material
or the ashes are smaller than the seed weights because of the
exhaustion of the seed reserves due to the release of CO2
in the atmosphere during respiration.

Another point deserves attention. In a
controlled atmosphere, the incoming air should contain some CO2
as a source for the photosynthetic process. To prevent any
external Ca contamination, this air must be filtered. It
should be bubbled through an HCl solution contained in a
flask, so that any trace of Ca, which escaped from the filter,
would be retained. To neutralize any trace of acid carried by
air bubbles, it would then be bubbled through a flask
containing a basic solution. The base should not be NaOH which
would absorb CO2. NaHCO3 was used
because it lets CO2 go through freely. We noted no
clues in the report we received from the USA which would lead
us to believe that these precautions were ever taken. After
scrubbing in acid and basic solutions, the incoming air is
scrubbed in a flask containing pure, twice-distilled water
before it lets CO2 go through freely. We noted no
clues in the report we received from the USA which would lead
us to believe that these precautions were never taken. After
scrubbing in acid and basic solutions, the incoming air is
scrubbed in a flask containing pure, twice distilled water
before entering the closed chamber. The chamber is maintained
at a low positive pressure of about 3 mm W.G. to prevent any
unwanted air intake through the gasket.

We will mention another study related to the
function of CO2. Photosynthesis develops very
poorly without this gas. It is only active for a very short
time in the morning when the plant absorbs the CO2
it released during the night by respiration. During the night
the plant draws on its reserves of oxygen and carbon and in
doing so, becomes weaker. The period of activity corresponds
to the time the light is turned on each day when artifical
light is used. The inverse experiment was also performed by
increasing the CO2 content of the air supply to the
chamber. Zundel showed that a large increase in the CO2
concnetration (about 10 times the normal concentration in
atmospheric air) led to an unsatisfactory plant metabolism.
There is excess carbon. This requires an abnormal increase in
both the absorption of carbon and in the decomposition, which
generates hydrogen and oxygen. As vein sections are too small,
the plant weakens and grows sickly. On the other hand an
increase of 2-3 times the natural CO2 concentration
in the air is beneficial. Some algae, chlorella for example,
are cultivated in atmosphere rich in CO2.

At this range of CO2 concentration we
observed a new phenomenon. The increase in Ca was very large
(500-600%) and it could not be ascribed solely to the decrease
in K. Analyses showed that Si decreased very significantly,
but insufficiently to account for the increase in Ca.

This phenomenon does not occur in a natural
atmosphere as was shown in the work with oat plants. Various
analyses, chemical as well as physical, supported this. In
atmospheres overloaded with CO2, there was a large
decrease in SiO2 stored in the seed. This was not
entirely surprising. We knew that in Nature there was a
partial inverse compensation between Ca and Si under specific
conditions, which have not yet been completely studied. We
studied the reaction Si14 + C6 >>
Ca20 in various books.

This explains why horsetail (equisitum) silica
was used in phytotherapy in antiquity to recalcify patients.
It was necessary to harvest the horsetail at the end of
spring, therefore at the end of the period of full growth, so
the silicon would be present as part of organic compounds and
not under the prevailing form of SiO2. Silicon is
stored as mineral SiO2 in the rhyzome of the pant
during fall and winter. Similarly, I made a detailed
presentation (See *Preuves en Biologie...*) of the
research by the great French chemist Vauquelin on the balance
of Ca in laying hens. These hens were only fed oats. "Lime"
was measured after precipitation of the carbonates and
phosphates contained in the oats and in the excretions from
the hens (eggs and droppings). A large increase in the "lime"
balance was noted during these experiments. Vauquelin thought
that this "earth" or lime (we would call it today an alkaline
mineral compound) could only come from another "earth"
contained in oats, silica. At the time, knowledge of the atom
was nonexistent. He could not imagine that the K19
+ H1 >> Ca20 reaction was
possible. During his measurements, he observed that the
increase in CaO was greater than the clearly measurable
decrease in SiO2. From this he concluded with a
very modern rational that Ca could not come totally from Si.
The problem still has not been resolved. We see how long
ago  (1799) the inverse relation between Si and Ca was
noted. We will not discuss here the hypothesis which would
explain the presence of Ca as coming from the excess CO2.
Research on this subject is still too speculative.

**(3) Conclusions ~**

We showed some of the weaknesses in the studies
made in the USA, or at least in the documents which were
forwarded to us. Even trained researchers with a background in
a different field can make mistakes. For example, Prof
Baranger decided to limit his study to a single vetch species,
Vicia Sativa. He selected it for a reason of convenience
because the seeds were very nearly round and easy to gauge,
without any regard for the vegetal biology aspect. To achieve
great accuracy in his measurements, he would weigh 10 seeds
from a Petri dish to 1/100 mg, which is difficult. Each batch
of control seeds was weighed separately. So was each batch of
plants, growing on two layers of extra-pure and ash-free
paper, moistened with twice distilled water. For the integrity
of the experiment, the data obtained on the batches of seeds
and on the batches of 3-4 week old plants were handed over to
a mathematician, specialized in statistics. Baranger always
analyzed a minimum of 100 batches of seed controls and of
300-400 batches of plants. The data obtained from these
hundreds of analyses showed that in average, there was a
significant increase in Ca in the seedlings during
germination.

However, this increase in Ca, which was
statistically established, looked too small to me. It was
neither impressive nor spectacular. The increase was usually
in the 2-3% range, and seldom did it reach 6-9%. I always
express reservations on the 1% accuracy level in the chemical
analysis of biological materials. Batches of seeds age.
Batches extracted from a given stock over a period of one year
are not endowed with the same vitality during their respective
experiments. Even a germination rate of 95% or more does not
guarantee 1% accuracy. Seeds, as with individuals of a same
species, have different innate strengths; their enzymes are
not equally active. Averaging the data from hundreds of
experiments obviously alleviates the problem created by these
differences. After selecting vetch seeds for handling
convenience, Baranger looked for optimal germination
conditions. He noted that in twice distilled water the
increase in Ca was very small. It increased somewhat up to
6-9% when a Ca salt was added to the water. After trying
various salts, he selected calcium chloride (CaCl2).
The additional Ca was added to the Ca content of the seed. The
sum was then subtracted from the sum of the Ca contents of the
plants and of the filter paper impregnated with the excretions
from the plants. Prof Baranger had to recognize that seeds,
stored for a long time, became moldy as soon as they were
dampened. Should then the transformations be ascribed to the
molds or to enzymes in the seed?

We noted that Baranger never mentioned the pH of
the culture medium in is reports. He found that additional Ca
strengthened the plant, but he apparently was not aware that
this effect was a calcicole property of vetch, which grows
better in the presence of a little Ca, in an alkaline soil.
This is not a clearly calcifuge plant, like oats, which
requires an acid medium, a generator of protons, in order to
produce the reaction. Vetch does not have the enzymes required
to form the additional Ca needed for plant growth. There ism
hence, a very small increase in Ca in the plant, usually less
than 5% in average. On the other hand, on the oat plant, the
increase is sometimes greater than 100% when it is cultivated
in an acid medium. Such is not the case when the variations
observed are 5% or less. For example, Barangers research on P
seems to show a decrease in P in the range of 1-1.5%. This is
questionable even if the precautions taken tend to validate
these figures. I should add that Barangers report does not
give any indication that he was worried about the artificial
light spectrum for the glass case he used in his experiments.
When I visited his laboratory, he had no phytolamps with
spectra adapted to photosynthesis. He used a Daylight-type
lamp, adapted to human vision. The few experiments performed
in sunlight were made under a glass cover which protected the
medium from falling dust, but not from floating dust. His
seedling trays were located in a narrow courtyard, or rather a
ventilation well, next to his laboratory. There was no direct
sunlight at all. All his seedlings were deficient in
chlorophyll. This might explain the small size of the
variations obtained.

In spite of every precaution he can think of, a
specialist in chemistry and biological chemistry may overlook
some aspects of an experiment, because he is too specialized.
Yet Baranger established, in the course of 10 years of
research, that in Nature there were variations in some
elements which could not be explained  by the theories
included in official teachning programs. Nature can do more
than chemistry. Baranger did not want to hypothesize on the
causes of the variations. He did not want to go against
established nuclear physical theories and he chose to limit
himself to his specialty and to remain exclusively in the
domain of experimentation. However, we see that it is
necessary to leave traditional practices and to use a large
number of different techniques which are often difficult to
unify.

It was even more difficult for two specialized
researchers in the USA to reach valid conclusions after making
only one series of experiments on small batches (usually 30
seeds each) and to avoid major pitfalls.

**Final Remarks ~**

I would like this last experiment to be
duplicated again in this university or another. Then the
points made in the present document could be taken into
consideration. As preparation, I believe that it is
indispensable to perform a series of experiments on oats only,
as this plant was the subject of many studies. These studies
allow the experimenter to locate errors, as there is by now a
solid database for oats established over a long period of
experimentation.

For health and age reasons, I cannot travel any
more and I declined invitations to travel in the USA, from the
Los Angeles Park Service, for example. Following experiments
based on my work, the Park Service modified its application of
fertilizers. The concepts of classical agronomy have been
borrowed directly from chemistry. They lead to excesses or
deficiencies injurious to the plant. What the plant needs is
not what is found in the mature plant, at the end of its
metabolism. We saw that this was true of Ca. It is also true
for other elements. These needs vary according to the soil and
the plant species (calcicole or calcifuge, for example). The
whole of agronomy must be reconsidered. The same is true for
animal husbandry, and human and animal dietetics. Many
dietetic or medical publications deal with applications of
transmutation, a property of living matter. These
transmutations are produced under conditions controlled by
nuclear physics and unrelated to the strong interactions which
lead to the atomic bomb. The Life process is gentle. Those of
my works which were published after1974 show how this
phenomenon can be integrated in the physics of neutral
currents or weak interactions.

*Note:* Other experiments were duplicated
in the USA in a school, in which a student presented a paper
several tens of pages long each year. The studies were related
to several kinds of plants (oats, wheat, soybeans, barley,
gumbo-okra) and to various elements (P, Mg, Ca, K, Na). I did
not mention them before, because it seemed to me that the
students overlooked some important parameters. They did not
contact me, nor did their professors. I only received the data
later. I did not have sufficient details to judge if the
excessive dispersions of the results should be ascribed to
errors in the growing procedure, to mistakes in the
preparation of samples to be analyzed, or to any other causes.

The same is true for the studies directed by
Komaki. I cannot accept the figures I received for various
elements in different kinds of pants: rice, soybeans, garlic
and azuki, a species of small beans. In fact, all these
studies show that the respective compositions of a plant and
of its seed are always different. Also in France working
groups of students preparing for the BTS exam (Brevet de
Technicien Superieur) in agronomy proceeded to do various
studies. However, the most important precautions mentioned
above were not taken. I could not comment on the variations
observed in the data. The same was true for studies made in
Switzerland, Germany and other countries. This is why I
thought it important to publish the information presented in
this document.

**Figure 13** [Not included here] ~ Groupe de
travail dune Ecole Technique Superiuer a Nantes, en 1976,
effechant des researches sur la variation du Ca dans une
avoine de variete Peniarth

---

**Chapter 8**

**Mass Spectrometer Analysis**

In the second half of 1979 I learned that the
microanalysis laboratory of CNRS just acquired a mass
spectrometer of a new model linked to a computer. It could
measure the elements quantitatively, as previous instruments
gave only rough quantitative indications: "traces", or if the
line was clear, the designation of the element was followed by
one, two, or three stars. Therefore, I had never been able to
cross-check positive ion contents by any spectroscopic method.
The determination of the P content was important as it was
accepted that the P/Ca ratio was close to 606.5 for oats when
P was determined by chemical techniques. Although I have
described above some aspects of the complex quest for various
P compounds, I ignored some other points. For example, the
presence of manganese prevents the analysis of P. It is
eliminated before molybdate is added. The Mn content in oats
is small and it is close to the Fe content. A part of the P,
remaining in the form of undetermined compounds, is ignored,
but it has little effect on the total results of the analysis.

For better accuracy, it was necessary to
eliminate the error on the low side which was due to seed and
plant incineration. For this reason, I requested from CNRS a
mass spectroanalysis of various positive and negative ions, in
order to cross-check the results obtained by the other
techniques. We sent to CNRS powder samples obtained after
drying the material at 85 deg C for 72 hours and grinding it.
This was below the limit of 100 deg C recommended by Gabriel
Bertrand, the temperature at which he operated. By working at
lower temperatures, the vaporization of some organic P
compounds and the formation of alkaline slags, insoluble in
subsequent reactions, were prevented. The data presented below
for P and Ca only are given for cross-checking purposes. Lets
keep in mind that only one cross-check experiment was made,
and that the values represent the average of two measurements.
I received a written confirmation of this data in early
January 1980. The figures are expressed in milligrams of the
particular element per 100 gr of dry material.

*S/P/V: P ~ Ca*   
Seed: 485 ~ 76   
Plants: 310 ~ 115.5   
Variation: =175 ~ +39.5

The P/Ca ratio is of 6.5, therefore normal.
Consequently, I believe the calibration to be correct. This
analysis, which was performed in a French laboratory, does not
represent an absolute proof. The experiment should be repeated
many times. As I was only looking for a cross-check and, as
the data was compatible with the data obtained by other
techniques, we may accept the data as reliable. They confirm
once more that some variations occur in the amounts of some
elements during the germination of oats, although no
additional amount of these elements was brought from the
outside during that period. It was not the purpose of the CNRS
experiment to prove that the increase in Ca was linked to the
decrease in P. Experiments of a completely different type
would be needed for that. It is obvious that there is no
quantitative relationship between the absolute values for Ca
and P. These discrepancies cannot be attributed to errors in
the experimental procedure as there are increases for some
elements and decreases for others. The figures tabulated above
are not absolutely accurate, because the dry weight of the
seed, from which the seedling originates, is not exactly the
same as the dry weight of the control seed. The average
weights for seed and seedling were computed over hundreds of
trial. These computations showed little quantitative variation
and no qualitative variation in the data shown above. This is
the reason why I do not reproduce here the details of these
experiments. They were published in the scientific press in
French, English, and other languages.

As the quantitative bases are different, it is
not legitimate to compare percentage variations, as some
people are tempted to do. After standardization, there is a
32% decrease in P and a 52% increase in Ca. It would be absurd
to state that there is an appropriate compensation around 44 +/-
8%.

After receiving a confirmation of the P
concentrations in oats at the beginning of 1980, I decided to
further investigate the relative importance of the Ca which is
insoluble in HCl. This is Ca linked to the phosphates. I
wanted to use these new figures to prove wrong those who still
insisted that the variations in chemical balances came from
inappropriate chemical analysis procedures. These statements
were unwarranted: furthermore, they contradict the conclusions
drawn by their authors. Zundel performed three additional
experiments on a total number of 870 seeds and seedlings. He
gave me the results in late November-early December 1980. I
received enough data to be able to form an opinion. Peniarth
oats used were supplied by INRA. The seeds weighed an average
of 34.21 mg each. Seeds and seedlings were then incinerated at
950 deg C and chemical analyses were performed using Prof
Charlots technique. The weight of the material which was
insoluble in HCl was 0.013 mg. The amount of Ca in this
material was then determined. The following results were
obtained:

Ca content in insoluble material per seed:
0.0032   
Average Ca content in insoluble material per seedling: 0.0319

The second figure is equal to almost 10 times
the first one. This confirms that an important molecular
transformation happened, and it transferred a very large
quantity of Ca into the insoluble state. Neglecting the Ca
linked to the insoluble material leads to a very sizable
underestimation of the Ca production during the germination of
oats. This contradicts the statements made by our professors
of botany a few chapters back. Soluble Ca measured in the seed
averaged over the 3 experiments had a weigh of 0.033 mg. The
average weight for each plant was of 0.0511 mg or an increase
in Ca amounting to 55%.

It is appropriate to state here the amount of Ca
which passed from the roots into the water of the cultivation
medium. I also requested an analysis of the water. Per plant
this amount was of 0.0051 mg, or approximately 1/10 the amount
of the content in the plant.

To summarize:

Ca: In Seed ~ In Plant

Ca insoluble: 0.0032 ~ 0.0319   
Ca soluble: 0.0350 ~ 0.0511   
Ca in water at end of experiment: --- ~ 0.0051   
Total: 0.0382 ~ 0.0881

Or an increase of 152% in total Ca.

The comparisons can only be approximate because
the measurement of Ca was only performed by chemical analysis
on the ashes. However, the direction the variations are taking
remains the same. The increase in soluble Ca from the seed to
the seedling should also be noted. It is 55%. The data given
by CNRS shows a corresponding increase of 52% after mass
spectrometer analysis and standardization to 100 gr of dry
material in both seeds and seedlings. I was not briefed by
CNRS about their procedure for preparing the material prior to
analysis by the spectrometer. I do not know if these
measurements were performed directly on a powder, on a spark
or on a solution. In any case, the two figures are very close
(52 vs 55%). In both cases there is a clear increase in Ca,
which could not possibly result from an underestimation of the
total Ca in the seed. On the contrary, if some techniques lend
themselves to underestimation, they concern the seedlings and
not the seeds.

**Conclusion for this Chapter ~**   
]   
I believe I have shown here that some chemists were conceited
to the point of being laughable when they systematically, out
of misplaced pride, rejected the findings of some of their
colleagues. Why dont they themselves perform repeatable
experiments with verifiable quantified data? Unfortunately,
many people tend to deny the validity of other peoples work.
They alone can detect the shortcomings of their peers; they
carefully avoid doing anything, so they do not run the risk of
being wrong. It is so much easier. This is not science
anymore; it is malicious polemics.

I believe that the scientists mentioned here,
all highly respectable in their profession, will accept that
their research quoted in this document, will be checked. They
all agree that analyses of various major elements show
completely different results for the seed and the plants under
strictly controlled conditions. Water used for the cultivation
is twice distilled; the air is extra-pure. No contaminating
mineral salts may be brought from the outside. They observed
the facts experimentally. They gave quantified data. But they
did not interpret their data, in the hopes of remaining
totally objective.

It is our role to interpret them.

I did not mention empirical observations in
industry, which were brought to my attention in 1960, because
I wanted to dedicate the first chapters of this book to the
increase in Ca in oats during germination. The curing of
potting clay by potters has been practiced since antiquity. It
is due to fermentation. So are the malting and the
fermentation processes in breweries. How many more examples
couldnt we mention!

---

**Part II**

**Explanation Of The Phenomena By Modern
Physics ~ Theoretical Study**

**Chapter 1 ~ Explanations From The Atomic
Particle Theory**

**Chapter 2 ~ A Few Examples Of Theories
Proposed By Physicists**   
**(1) Process developed by a US Army scientific department ~
(2) L. Romanis contribution ~ (3) Theory proposed by A.
Dubrov ~ (4) A few interesting points of view expressed by
physicists ~ (5) O. Costa de Beauregards theory**

**Chapter 3 ~ Addenda To The Theoretical Study
Of Low Energy Interactions Applied To Particular
Transmutations**   
**(1) Effective section ~ (2) Isotopic variations ~ (3)
Nature operates at a finer level than man ~ (4) Changes in
our understanding of some aspects of physics and weakness of
this understanding ~ (5) A few arguments against a unified
theory for electromagnetic and weak interactions ~ (6)
Intermediary vector bosons**

"Felix qui potuit rerum conoscere causas ~
Fortunate is the man who succeeds in knowing the (secret)
causes of things" ~ Virgil (*Georgics*)

**Chapter 1**

**Explanations From The Atomic Particle
Theory**

In order to explain a phenomenon, one must place
it in a framework accepted by at least the majority of
scientists.

After I established the existence of biological
transmutations, I suggested global formulae at the atomic
level. This was an entirely new idea at the time. It was then
impossible for me to place these formulas in the frame of the
strong interactions of the atomic bomb type, which was
generally accepted. I was sure of the experimental results but
these results could not be explained by the prevailing atomic
physics of the time. I did not challenge this well-proven
discipline in the least. As I had such strong evidence, I
stated instead that we were dealing with a completely
different phenomenon outside the realm of strong interactions.
I had no accepted theory to propose, but I firmly stated that
the strong force theory did not apply to the cases at hand and
that it was up to the physicists to find another theory.

Theories are built on facts and not the
opposite, especially when it is obvious that specific
phenomena cannot be explained by these theories. Too many
physicists keep in forgetting it. I had the opportunity of
mentioning some exceptions to this unfortunate behavior; among
the exceptions are the respected scientists: O. Costa de
Beauregard, R. de Puymorin, L. Romani, J. Barry and others in
France. In Russia I referred to Dubrov, Nejman and Korolkov in
my previous works; several others wrote to me on this subject.
In the USA, there were Dudley, Myers, Maxey, Bird and others.
In Japan, there were Sakurazawa, Odagiri, Maruyama and others.
Zundel and a few others, such as J. Boucher, performed
experiments and did not formulate any theories. This was also
the case in the USA, Argentina, Canada, and India as well as
in other countries.

As there was no theory to explain these
phenomena, I could only offer analogs to show that various
structures of the components of the atomic nucleus were
possible. I did this over a period of years. I showed that
some schematic explanations, in fact simple vulgarizations
based on the average energy per nucleus concept, were only
figments of the mind. I showed that they could not be verified
and that they were certainly wrong. There was room for other
analogs.

An analog necessarily gives a wrong view of a
phenomenon. It leads to representing actions at the atomic or
subatomic levels as if they were working at the level of our
senses or of the cell. In fact, these actions cannot be
detected at the molecular level, even less by our senses.

These considerations are only secondary, because
the general public is primarily interested in applications.
Fortunately for our successors, we will leave them much to
discover. As important as application may be, it is not
everything. There is also the satisfaction of knowing, the
interest found in abstract knowledge, which is a strong
intellectual stimulus.

We had to wait 15 years, until 1974, before
theoretical physics brought us the elements which were
formerly beyond our reach. The readers, who read the previous
work I published in 1975, may have noted on page 281, that on
July 23, 1874, I wrote to the physicist O. Costa de Beauregard
to confirm the existence of neutral currents. These currents
were first discovered in Weinberg and Salams theory. I
believed that this theory could provide a base for the
explanation of transmutations at low energies. This supported
the role of neutrinos in the reactions I had proposed, a role
I had suspected. By the second half of 1974 de Beauregard had
succeeded in refining the Weinberg-Salam theory and adapting
it to my work. This adaptation was included as an epilogue to
my book, dated December 1974 which was already at the
printer.  Dare say that shortly after that, in January
1975, a Nobel Prize official delegate nominated me for the
prize in Physiology and Medicine. The physiologists did not
want to take precedence over the physicists. Weinberg received
his Nobel Prize in Physics only in 1979. This confirmed that
this theory, the one I mentioned in 1974, was valid and
internationally accepted.

Those who have little interest in theoretical
considerations may choose not to read Part II of this book,
but I believe that many will try to understand it. I will
attempt to be understood by the general scientific public;
only the final chapter will be written for nuclear physicists.
I will keep in mind that for many of these, this is a
completely new and unknown subject. Due to their
ever-increasing specialization, nuclear physicists tend to
limit themselves to the physics of the strong force and to
focus only on some parts of this widely expanding science. For
them, this will be an introduction to the physics of weak
interactions, a subject which is still little known,
especially in this form. This branch of physics is too new to
be the subject of many high quality publications. There is
always a lag of several years between discoveries, the
synthesis of the new information they brought, and the
acceptance of this new information by the majority of the
theoreticians. When I started planning for this book in late
1978, I thought I would complete it in 1979, and at that time
no works on the physics of the weak interactions were
available. I decided then to include a chapter on this
subject. It is indeed somewhat abstract, but I believe it will
be useful to the average scientist unfamiliar with this branch
of physics. The situation evolved after the award of the 1979
Nobel Prize in Physics. The subject is now better and more
commonly known; I decided to modify the plan of this book. It
is impossible to treat a subject in full evolution so the book
remains up-to-date for several years. Therefore, I thought
that the scope should be modest and kept general so it would
not be contradicted by the discoveries in process. These
discoveries fundamentally change the picture presented below.

I will not mention strong interactions, which
does not mean that I reject them. This would be silly on my
part. However, it should be recognized that too many
physicists and too many of their followers, scientists of
various backgrounds, tend to grant too wide a scope to the
data in nuclear physics. One can always argue about an
extrapolation and sometimes an extrapolation may be plainly
wrong.

I do not wish to argue about Einsteins laws. I
accept them, although I do not always agree with the people
who use them any old way. The postulates, on which they were
based, should always be kept in mind. Indeed, Einstein never
extrapolated these laws. E reminded his dogmatic worshippers
about their limits. In particular, he noted that his laws did
not apply to biology. He could not say why, but it was obvious
that biological experiments were not ruled by his laws.
Einstein did not know about the neutrino when he formulated
his laws. He only knew that his knowledge was limited and that
a lot of nonsense had been spoken and taught about the
restricted relativity law E = MC2. In this law C2
is a constant and M is proportional to E (and vice versa). It
always remains a linear law, a first degree curve; in other
words, a straight line. This is why he had to search for his
General Relativity Law, in order to explain the curvature of
light in the vicinity of large masses such as the sun or any
large star. Curvature means change of velocity, a factor of
the second order. So many scientists forget that M is not the
stationary mass designated as Mo; it is in fact a relativistic
mass.

One often forgets also that the mass-energy
conversion is not a simplistic rule. We do not know how to
convert any old mass to energy. We first have to use some
energy which produces anti-matter which in turn gives energy
after annihilation. We do not know how to destroy a proton or
a neutron. These particles remain unchanged in an atomic
explosion or in a fission reaction. Only a small part of the
linking energy between nuclei is used. I do not intend to
discuss the heavy particles, the baryons, or their components,
such as the quarks, or even the gluons which supposedly link
the quarks. There are vast problems in this area which is in
full evolution, but these problems do not concern the fields
of weak energy. Indeed, we will mention the hadrons in our
study of weak interactions. The first statement on the
existence of weak interactions was made soon after the
discovery of the neutron. Obviously, a neutron was not simply
a proton plus an electron. There was a particle, which could
not be detected at the time, but which was necessary to
restore mass balance. It was named neutrino. A very careful
study of natural radioactivity showed that there was an
electromagnetic phenomenon, the emission of one electron, but
that there was also the emission of one anti-neutrino.
Similarly, we will introduce the notion of proton movement in
the course of our study of weak interactions, in relation with
other phenomena such as the tunnel effect or the effective
section.

We will study these phenomena a little later.
Other particles must also be introduced. They are necessary to
the theory, but they have not been experimentally isolated
yet. These are some of the essential elements of the theory,
for which the 1979 Nobel Prize was awarded. They are the
intermediary virtual vector bosons. We will spend a little
more time on them.

As early as July1974 I had focused on Weinbergs
theory, which was followed shortly by Salams theory. I
related this fact in a letter excerpt in the book given to the
printer at the end of 1974 and published in early 1975. I
applied this theory to a biological phenomenon I had
discovered. But what is more important? The proof of the
existence of a biological phenomenon or the theory behind it?
It is not up to me to judge. I cannot be the judge and party
at the same time. Furthermore, how should we judge when the
problem straddles across biology and physics, and when
specialists of either discipline will be called upon to cast a
judgment. Each one tends to form an opinion on the basis of
his own knowledge. It is only human. There are no
interdisciplinary Nobel Prizes. There is a Prize in Physics,
another in Physiology or Medicine. Specialization is a rule
everywhere, especially in physics. The biologist does not want
to innovate and he follows the physicist. This is why the
official delegate who nominated me for the 1975 Nobel Prize I
Physiology or Medicine was not followed by his colleagues on
the Nominating Committee. He was not a Frenchman. Nobody is a
prophet in his own backyard. Only in 1979 did the Physics
Nominating Committee award their prize for the Weinberg-Salam
theory which I had adopted 5 years earlier. Lets not dwell on
the past. The essential was to prove that a fact
scientifically established after many indisputable experiments
was in line with the classic theory. I am trying to show here
that the clear evidence obtained for this phenomenon and its
multiple implications, represent a major turning point for
Science internationally. Theories other than Weinbergs were
proposed throughout the world to explain the phenomenon. I
believe that the most widely accepted theory was proposed by
the physicist de Beauregard. It was refined during the second
half of 1974 and its principle was then accepted by Bernard
dEspagnet, a well-known atomic particle specialist. The
theory was summarized in my book of 1975. It was not refuted,
but it was only a schematic explanation. I completed this
theory by introducing the intermediary vector bosons in
various publications as early as 1976. This is the reason why
I will give more attention to this theory and I will describe
only briefly a few others, which incidentally provide very
interesting complements to this theory. I will describe this
complementary information in greater or lesser detail.

---

**Chapter 2**

**A Few Examples of Theories Proposed by
Physicists ~**

**(1) Process Proposed by a US Army Scientific
Department ~**

A department of the US Army Scientific and
Technical Services headed by S. Goldfein studied my research.
The team gathered for this purpose worked on the report from
December 1977 to April 1978, and the report was published in
May 1978. It was distributed to numerous specialized service
in the various branches of the Armed Forces (Army, Navy, Air
Force, General Services). It included 28 pages, not counting
the cover, and 8 figures. In it Goldfein proposed an
explanation based on physical chemistry, delineating a
possible process which must still be developed and defined
more precisely.

Numerous calculations made by the authors of the
report, too few according to them, showed homogeneous results.
They showed that the reactions originating from my research
confirmed a gain in energy. There was a new source of energy,
which had to be investigated more closely. In our time no
source of energy should be neglected just because it was
insufficiently studied. This was the reason this agency,
highly respected worldwide, decided to intervene.

Classic physics shows that K + H >> Ca +
0.008 a.m.u. This means that in the reaction v + H + K
>> Ca + *v*, the energy taken by the outgoing
neutrino v should be greater than the energy brought in by
the incoming neutrino v. In other words, in biology the
production of energy should not be limited to the sole
exoenergetic chemical reactions. Exoenergetic reactions of
physical origin should also be considered, although the
energies involved are modest compared to the energy of fusion
by the strong interaction. They are far from being negligible,
as they result in a positive balance of approximately 40% for
the cases studied.

We noted from de Beauregard: *v* + *p*
>> *v* + *p* with *v* =/ *v*
(see the last chapter in our book of 1975). The US Army
Scientific Services state: v >> v and v ~ v + 40%.
Could this be attributed to a fusion process produced
following a process other than the strong interactions
process?

The report describes an example based on the
oxidative phosphorylation process in mitochondria. Some animal
cells include up to 7,000 mitochondria. From the energetic
point of view, the active molecule is ATP after chelation of
one Mg atom (Mg-ATP) under the action of an enzyme, Mg-ATPase.
I discussed this process in more details in my book of 1975,
in particular on page 85. I first presented the beginning of
its study in my book of 1968, now out of print.

The US Army study shows also an action by
D-ribose molecules interacting with the Mg-ATP to produce a
rotation of the acyl-oxygen dipoles linked to P atoms.
Schematic representations and computations lead to a helix
with H+ ions in an unsaturated ionic structure. A link is
established between the D-ribose and the form gamma oxygen.
The Mg++ chain electrons (axial chain of 10 Mg++
in the study) produce an oscillating electric field leading to
a resonance. An H+ ion, introduced between the
components of an OH and gamma-O pair, ends up on a circular
helix trajectory of approximately 30 Angstroms diameter under
the dipoles impulsion. Following this hypothesis, the
hydrogen H+ positive ions would finally acquire a
very high rotational velocity. This would be a relativistic
velocity, so to speak, due a cyclotron effect, such that H+
would cross the potential barrier of an atomic nucleus and
penetrate into it. If the proton receiver is an atom of K the
reaction would be: K19+ + H1 >> Ca20.

The development of this hypothesis fills about
14 pages of the report. It is very interesting because it
provides an explanation for a physico-biological process
partially established by various studies. This hypothesis
should be applied to other cases. I thought it was opportune
to mention it here because the US Army could not pursue the
research for lack of funds, as it commonly happens everywhere
in the world. At least the agency wanted to show the solid
bases for the hypothesis.

In the first part of this chapter I did not
intend to give my full and unconditional approval to the
study. The author of the report was fully conscious that
complementary studies were necessary and that the study
completed constituted only a first step. He would have liked
to receive sufficient funds to be able to take one more step.
At the time I am writing these lines, this has still not
occurred.

It is obvious, for example, that special
procedures should be applied for the measurements related to
energy balances. These measurements are very complicated.
Known calorimetric methods cannot be applied, because
neutrinos intervene, as we are here in the domain of weak
interactions. Neutrinos interact only very seldom with matter,
A large part of the energy is carried away under a virtual
form, so to speak. It goes through space without affecting our
senses or our measurement instruments. How can we measure it?

How can we measure the energetic contributions
from enzymes or from ATP? Here we are dealing at the molecular
level. There are uncertainties in the values measured
indirectly by methods based on theories which may be
questioned in the future.

Many more points need to be investigated more
thoroughly. Much uncertainty remains regarding the
quantitative study of energy balances and also regarding the
qualification of the operator. Many questions should also be
raised on various theoretical points. It is pointless to list
them here. The main point is the experimental study leading to
the confirmation or the refutation of a theory. It is not the
blind respect of theory.

I congratulate S. Goldfein for his report.
Synthesis of physics and biology, such as the one he
presented, are rate. There is here a wide filed for research
which is not even being explored in most countries. Some
aspects of the physics were left aside by the US Army
scientists, weak energy interactions in particular. Few
traditional physicists knew about the work of Weinberg and
Salam before it was widely publicized after the Nobel Prize
award at the end of 1979. S. Goldfein and his associates
stated some synthetic considerations of the highest interest
and their study is very encouraging. I have condensed too much
the published report any my summary may be inaccurate, because
incomplete. The subject is so vast that it is difficult to
condense. Some American magazines presented summaries even
more succinct than mine in order to prod the reader to refer
to the original report. The reputation of the agency which
issued the report is a guarantee that the study was done in
earnest. My research reached renowned agencies throughout the
world. Its value was confirmed by my nomination for the Nobel
Prize by a scientist belonging to this internationally known
agency. I started my presentation with the US Army study,
because to my knowledge, it was the most detailed study
published by an author and because the synthesis of physics
and biology is most interesting despite the reservations made
by theoreticians on some of its pints. The future alone will
tell.

**(2) L. Romanis Contribution ~**

I must also discuss at some length a study made
by the physicist L. Romani because it was not published
insofar as I know. L. Romani is a well-known fluid mechanics
specialist. He is known in particular for his remarkable
contribution to the original, simple and efficient solution of
specific technical problems in the field of wind energy
(automatically controlled windmills) and of wind effect
prevention (on suspended  bridges, for example). He is
the director of the Eiffel Laboratory, in which air flow
studies are made for the purpose of improving aerodynamic
shapes (aircrafts, automobiles, etc.). Eiffels laboratory
facilities include a wind tunnel, which is used to check
computations on scaled models. This work brought L. Romani to
reexamine some aspects of acoustical waves and more generally
of all waves.

His keen understanding of energy problems
related to air flow brought hi to study my work because of its
implications in the field of energy. As soon as 1963, he
proposed for it a purely physical examination which I
presented in part in a book published in 1964. The validity of
his calculations was accepted by two respected scientists
mentioned in his paper. However, it seemed that the
generalization of the phenomenon ran against some observations
pointed to me by a well-known specialist of wave mechanics.
For this reason I did not publish the remaining of Romanis
study in my subsequent publications. I did not even include
the text published in 1964, as this study presented only a
historical interest.

However, Romani did not forget the matter. To
this day he was not able to propose a global explanation of
the process encompassing all the points established in my
research. Nevertheless he showed that one should not forget
particular fundamental points resulting from the study of wave
phenomena if one does not want to become lost in farfetched
theories.

This respected physicist published a basic work
in two volumes on his theories, *Theorie Generale de
lUnivers Physical*... [blurred line in photocopy]... (A.
Blanchard, Paris). He frequently used dimensional equations.
As far as my work is concerned, one should refer mainly to
partial studies, in particular to mimeographed copies of
lectures he gave at the Sorbonne and in various other places
mainly from 1976 to 1978.

In November 1976, for example, he expounded
various original points of view on energies at Cercle de
Physique A. Dufour in relation to Relativity and energy
transmission via the ether, which he still fully supports. He
defended his position on this subject in multiple lectures. He
accepts four types of energy, as everybody does today in a
non-definitive and non-limitative way. He also stated the
following:

(1) The body on which the gravitational field is
exerted, or mass, has the dimension of an inverse length 
L-1;

(2) The body on which is exerted the weak
nuclear field, or hypermass, has the dimension of a Gauss
curvature L-2;

(3) The body on which the electric field is
exerted, or charge, has the same dimension as the ratio of a
torsion by a curvature. It is a pseudo-scalar number;

(4) The body on which the strong nuclear field
is exerted has te same dimension as a torsion, L-1.

One can see here some of the fundamental
differences in the nature of the fields for the four types of
energy. These lead us to express some reservations on some
unified theories which can only unify everything in confusion
or in a generalization devoid of precise meaning.

I will come back to some of the differences in
the main characteristics of the representative waves for these
forms of energy, as they were outlined by L. Romani. I will
only mention in passing various pertinent comments made by L.
Romani, which are forgotten too often. According to him,
photons are not waves but they are pairs of whirls. This
concept leads him to original views which are far from being
unanimously accepted by physicists. Waves do not carry energy;
they carry information. Romani is far from admitting the
classic definition of information as given by Brillouin and
others. To consider information as the co-logarithm of entropy
would be a mistake, as information cannot consume any energy.
Otherwise the French language would not make sense anymore!
But is it all that new? Blaise Pascal wrote: "I never argue
about a name, provided I am told about the meaning which is
given to it". Dialectic is still with us. A piece of
information is a data, something abstract; it is something
potential. It is only when the information is used that there
is energy consumption. The whole entropy question should be
reviewed, as it is generally agreed. In 1977-1978, J. Tonnelat
addressed this problem in a work in two volumes. He showed how
poorly defined the problem was. This problem is extensively
reconsidered in J. Tonnelats books. The reader will have a
different view of the entropy (and negentropy) problem after
reading them. "It is not right to consider entropy as energy,
although both are dimensionally equivalent" (p. 158). One
should also keep in mind some considerations which the author
does not even mention. In particular, and I insist on this
point, the problem of energy in living matter should not be
looked at in the sole light of thermodynamics. Lets not
forget the action of neutrinos coming from the ambient medium
(lets say cosmic; lets not be fooled by words) on the life
phenomenon. This is an essential point for our work, as we
will see later.

Lets come back to a remark by L. Romani: a wave
only propagates a movement. The associated photon
(electromagnetic energy) carries the information. In each
point, at every instant the kinetic energy of the undulatory
movement is derived from the potential of the Ether. There
would be no energy transport by the waves of the local Ether.
These waves are used as signals; they transport the
information. Information initiates a similar movement in the
receiver, which derives the necessary energy from the Ether
and transforms this energy into kinetic energy, the only form
of energy we can perceive. This is why a wave appears to carry
energy. Romanis Ether concept is new; it is the "tense"
Ether.

**(a) Waves and Low Energy Transmutations ~**

I will not summarize here L. Romanis views on
waves. He dedicated to them Ondes Inconnues (which was only
mimeographed), a very dense work, too long to be summarized.
However I will refer to it in the later part of this book,
because Romanis views on waves are too important to be
ignored or forgotten. It is essential to keep them in mind in
order to remember the fundamental differences between the
various manifestations by other forms of energy fields. For
the time being, I will only quote a few statements made by
Romani:

(1) Strong nuclear energy field waves are either
centripetal or transversal and circularly polarized;

(2) Weak nuclear field waves are longitudinal
and circularly polarized.

I emphasize that only circularly polarized
energy forms, as defined by Romani, seem to be capable of
producing element transmutations. This is a personal comment
and it should not be attributed to Romani. I am only borrowing
his wave classification, not the effects of the waves, which
he did not mention. Wave effects were derived form my studies.
I do not pretend to establish a general and absolute rule,
valid for all transmutations, but only for the specific
transmutations I was able to check.

Gravitational waves (if there was such a thing)
would be longitudinal and not polarized.

Electromagnetic waves would be transversal with
a rectilinear polarization.

It is often said to simplify that "all simple
displacements are either rotations or translations.
Furthermore, a wave is either transversal or longitudinal". In
short, it follows that:

(1) Gravitational waves are longitudinal and not
polarized;

(2) Weak field waves are longitudinal and
circularly polarized;

(3) Electromagnetic waves are transverse and
linearly polarized (in a plane perpendicular to the direction
of propagation);

(4) Strong field waves are transverse and
circularly polarized.

The first two longitudinal types can pass
through shields, just like sound waves.

In fact, undulatory phenomena are seldom simple.
In the course of their propagation, waves may differ from the
original forms in which they were emitted. Transverse waves
may be linearly polarized in the plane perpendicular to the
direction of propagation. Hybrid waves may occur such s waves
polarized in a plane including the direction of propagation.
Others are transverse and circularly polarized in the plane
perpendicular to the direction of propagation. They could
consist of the sum of two conjugated waves in quadrature.

The wave question is complex and I cannot
suggest any work covering the whole subject. The course by J.
Bo and N. Hulin-Jong (Hermann), Ondes
Electromagnetiques-Relativite, brings up interesting points of
view, but it tackles only one type of wave and does not
provide for any comparison, as it deals only with
electromagnetic waves. These waves cannot cause weak energy
transmutations, which are associated to waves of a completely
different nature.

I will come back later on specific ideas of
Romani which I associated with some effects which he did not
mention. These effects are in line with the additional
information that Romani sent to me in May 1977 and that I
discussed at the ARK-ALL inter-university meeting of June
1977. My paper was printed in *ARK-ALL Publication 1978*,
Vol. 4 (1): 49-63. I will have the opportunity to come back
later to some fundamental differences between weak energy
fields and other types of fields,

**(2) Theory Proposed by Dubrov ~**

In various letters, Alex. Dubrov, Dr in Science
and Member of the Geophysics Institute of the Sciences Academy
of Moscow, shared with me his ideas on the theoretical
mechanism of biological transmutations. I will give here a
brief summary of the information contained in The Geomagnetic
Field and Life, a book he published in the USA in 1978. This
was a corrected and much enlarged version of the book in
Russian published in 1976. Dubrov sent me a copy of his
initial book in Russian.

*The Geomagnetic Field and Life-Magnetobiology*
is a big book published by Plenum Press, NY. It contains a
bibliography of over 50 pages as well as 82 figures. In this
work the author gives many experimental results related to
electromagnetic effects of the earth on live matter. Some of
the points studied were accepted by Prof G. Piccardi, formerly
Director of Physics Laboratory of the University of Florence.
I met Prof Piccardi several times and he sent me his book *The
Chemical Basis of Medical Climatology*, published in the
US in 1962 by C.C. Thomas, Springfield. He spent much time
studying the effect of solar fields on the rate of
precipitation of colloids, on human colloids, cells and blood
in particular. He published *Biolelectric Rhythms in Human
Blood* in Holland, 1970.

Dubrov believes that geomagnetic effects are
exerted at a very low level, even at a subatomic level, in the
framework of the weak energy interactions. Geomagnetic field
changes could reverse the spin of elementary particles,
transforming a **[ 1 sentence missing text ]**. In some
cases they could cause dissymmetry by mirror effect (a 180
degree rotation). These molecular modifications in turn could
alter the oscillatory rhythms in several parameters of the
living organisms. The infractions to the symmetry law are
important. They remain very much in the actuality, as attested
by the 1980 Nobel Prize in Physics. This prize was awarded to
a physicist who researched some specific infractions to the
law of symmetry. His work was done some time ago, but the
award shows how much interest the infractions to the law of
symmetry still arouse.

In 1980 Dubrov published another book in Russian
on mirror symmetries. He sent it to me, but I do not know if
it will be published in English. He advised me of the
publication by Planum, NY in 1981. This new book will be
co-authored by an America named Pushkin. In his book of 1978,
Dubrov applies the geomagnetic field to biological
transmutations, following the formulas I proposed several
years before. He mentioned these formulae in his book of 1980.
It seems that he did it from memory as he made some errors.

He quoted some studies which show that magnetic
fields of 1,000-5,00 oersteds modify the amounts of dry
material and ashes in plants as compared to seeds from which
they originated. No minerals were brought from the outside
during these studies. The same fields cause changes in
oligo-elements according to these studies, which could only be
explained by a transmutation of some elements.

The cumulative effect of changes in the earth
magnetic field, due to earth rotation, of proton showers and
other factors, could produce structural inter-chromosome
inversion by rotating one chromosome segment. In so doing it
would modify the coding for the synthesis of enzymatic
proteins. According to Dubrov, the genetic code would be based
on a pentametric symmetry and the RNA triads would be arranged
in an icosahedron. If these triads would be arranged in an
icosahedron. If these triads were rotated by 180 degrees,
alterations in residual amino acids could result. A change in
the position of a single asymmetric atom is sufficient to
modify the property of elementary particles which are becoming
symmetric. In this fashion racemic tryptophan could be
transformed into laevo-tryptophan. Lets remember the
importance of asymmetric carbon in organic chemistry.

A magnetic spin reversal could be the initial
cause of this transformation according to Dubrov. Elementary
particles are very sensitive to variations in the parameters
which involve weak energies. In this way there would be a
correlation between macrocosm and microcosm.

Geomagnetic field effects should be studied more
closely in the light of the progress made I wave mechanics,
communications, cosmology, and geophysics. They show tat there
is no theoretical impossibility in accepting that some
biological transmutation do not belong to the domain of strong
interactions and that they can be explained by weak energy
interactions.

Dubrovs study is most interesting because it
emphasizes the mechanism ... **[missing page in text ---
badly blurred photocopy]**

According to Dubrov, there could be no
significant interactions between neutrinos and living matter
without actions by the enzymes, whatever the direct cosmic
effects. As member of an agency affiliated to the University
of Moscow, Dubrov focuses on a point worthy of additional
studies. For the time being he shows mainly the directions
which may lead to the explanation of the phenomena. He barely
touched on their quantitative study.

**(4) A Few Interesting Points of View
Expressed by Physicists ~**

Various theories were proposed to explain the
phenomenon of transmutation by living matter.

The physicist Rene de Puymorin thought of a
stationary wave mechanism similar to the sound mechanism.
Based on the computation of several specific data, he
concluded that electrostatic repulsion was wavelike and that
it was not continuous or hyperbolic. He states its wavelength
and from there his computations enable him to determine other
aspects of the potential barrier. His study is primarily based
on a specific concept of the electron structure. I am afraid
of distorting his point of view in summarizing it too
succinctly. The reader should refer directly to the work *LOrigine
de la Gravitation*, published in 1975 by La Pensee
Universelle, Paris. In this book R. de Puymorin expresses
different views on various problems presented in a fairly
simple and very personal way. It is food for thought. This
small book of 64 pages is easy to understand. Puymorin
discusses biological transmutations in 11 pages only. He sent
me several other more extensive studies which had never been
published. I cannot refer the reader to them, and I have no
room here to include the various notes puymorin sent me.

**(5) Costa de Beauregards Theory ~**

As early as 1963 the physicist O. Costa de
Beauregard saw the possibility of introducing the action of
neutrinos in the reactions which I published in 1960. I noted
this possibility in my book *Transmutations a Faibles
Energies*, published by Maloine in 1964. C. de Beauregard
said he was convinced that the energy balance in my reactions
could only be understood though the effect of massless and
chargeless particles.

He immediately ruled out neutrinos, of which he
thought first, because the conservation principles were not
respected. Only 10 years later could he formulate a theory
satisfying these objections, at the time the neutral current
theory was introduced. This theory constituted a major
progress in the physics of elementary particles.

This theory was summarized by the simple
formula: *p* + *v* >> *p* + *v*
, or: iN + p1>> pN +
*v* .

I had observed that such reactions were
experimentally verified only for odd A nuclei and that they
yielded modified even A nuclei with a 1H1
(or 1p1) proton. At the time none of my
experiments showed that it was possible to jump from an even A
to the A of rank immediately superior. No experiment showed
either that it was possible to go down scale from N +1
to N by a single step.

We had: p =/ *p* and *v* =/ *v*
because the energy of the incident *p* proton was
different from the energy of the *p* proton included in
the nucleus. A neutrino of *v* energy was absorbed and a
neutrino of *v* energy was re-emitted. The energy
difference was emitted into the ambient space without thermal
effect or without any other effect on the material. This
explained the energy balance observed. Such a formula
satisfied the most rigorous conservation of energy, mass,
impulse, angular momentum, spins, baryonic and leptonic
numbers, etc. It could not be refuted with any theory.

I will not give more details on de Beauregards
theory. He presented it himself in the epilogue of my book, *Preuves
en Biologie de Transmutations a Faible Energie* (Maloine,
1975). In the last chapter I reported on our active
correspondence during the time de Beauregard was working on
his theory. The principles of this theory came to his mind in
the spring of 1974 after the existence of neutral currents was
confirmed. He asked me to insert it at the end of my book,
which was then at the galleys for publication in 1975.

A neutrino provided the necessary impulsion so
that a proton can be included in an atomic nucleus by tunnel
effect in accordance with quantum mechanics. This was the
basis of de Beauregards theory. For example:

V + K19 + H1 --> Ca20
+ *v*1 ( with *v* =/ *v* )

The *v* neutrino is expelled in order to
reestablish the energy balance between the two sides of the
formula. The incident neutrino *v* provides the initial
energy or the impulse which permits to introduce the H+
into the nucleus of the potassium atom.

Costa de Beauregard noted that his theory was
only a preliminary framework and that it had to be completed.
To this end a change in the transition natural possibilities
under the effect of an information structure inherent in the
life phenomenon, had to be considered, according to him.

The theory still holds after 7 years if progress
in the physics of elementary particles. As soon as 1976 I
introduced various complementary concepts to enlarge and
further document some theoretical physical aspects of the
basic principle which was published in early 1975. These
complements engage my sole responsibility. They cannot be
attributed to de Beauregard I any way.

---

**Chapter 3**

**Complements To The Theoretical Study
Of Weak Energy Interactions Applied To Some
Transmutations**

As soon as 1975 I studied some complementary
ideas which I thought necessary in order to enlarge the
theoretical physics basis laid down by de Beauregard.

Both of us lectured in London in 1975 in front
of a large audience during the May Lectures and the morning
after in front of specialists at the Kings College.

These developments were the subject of various
publications in French and English from 1976 through 1978,
especially during the latter year. Different aspects of
physics and progresses realized in this science since 1975 led
us to define more precisely the initial concepts. I will
briefly describe here the scope of our knowledge as of the
beginning of 1981. Fundamental concepts are too often unknown
of the physicists bogged in obsolete ideas. These concepts
have been insufficiently publicized, unfortunately. This
explains why these physicists are taking positions
incompatible with the new science of the weak energies
interactions. I can only discuss here a few fundamental
points.

An objection, still raised in 1980, is that the
effective section of interaction between neutrinos and protons
is too small to permit a weight change in the material. O.
Costa de Beauregard had precluded this objection in his ending
note to my book of 1975. At the time he based his concept of
effective section only on classical theoretical considerations
accepted by most physicists.

Already in 1974 this notion was contested. It
was based on the results of statistical evaluations which were
too general, oversimplified, sometimes purely imagined and not
confirmed by precise calculations. Incidentally, one did not
know how to perform these calculations at the time. The
question was more complicated than it was assumed at the time,
and in a sense it was premature. The subject was discussed in
lectures given during the 1974 summer session at
Gif-sur-Yvette. In the June 1974 of *Physics Today*, it
was noted that the neutrino-hadron effective section did not
have a fixed value and that it did not vary only with the
energy of the incident neutrino. It was proportional to the
square of the atomic mass of the nucleus. On other words, if
the target was a K39 nucleus, then the square of this number
should be introduced in the calculations. A considerable scale
change resulted. A neutrino, which passes through a nucleus,
comes close enough to all the nucleons in the atoms to react
with each one. It is not absurd to conceive that the electrons
other than the K orbit, revolve around the concentrated group
of nuclei, when nuclei are very close to each other. This is
the case in molecules, in which nuclei keep only around
themselves the two electrons revolving on the K orbit. These
electrons can even revolve in the interspace between nuclei.
In this way there are many different orbits. Some organic
molecules may have molecular masses reaching several tens of
thousands, even hundreds of thousands. The effect of an
incident neutrino is felt by the whole nuclei cluster.

Additional studies were going to support my
ideas. In a 2-page paper published October 6, 1975, in *Physics
Letters* entitled "Are Solar Neutrinos Detected by Living
Things?", Ruderfer quoted the results of experiments performed
on the giant calmar. He computed the effects of these
neutrinos on mammal brains, as he had noticed that the
sensitive part of a neuron (axons and dendrites) can amount to
100-1,000 times the volume of a body cell. This brings us to
review the notion of capturing section, or more precisely, of
effective interactive section. A 5-page study in English by
Ruderfer, "Neutrino Structure of the Ether", published in *Lettre
al Nuovo Cimento* (May 3, 1975), makes for an interesting
read. So do other articles on neutrinos published by the same
author in this periodical as well as in other American
magazines. Some of these articles date back to 1968 and they
deal with physiological and psychic points of view.

**(2) Isotopic Variations ~**

I mentioned several times the wrong postulates
accepted as classic by some physicists and phytobiologists.
These errors are taught in schools of science, in schools of
agronomy of high level, etc. Among these the invariance of the
isotopic composition for a given element is most commonly
accepted.

I pointed out for example that photosynthesis is
not a uniform phenomenon for all plants. His was a recall for
some and a first for others.

Isotopic variations explain the discrepancies in
atomic mass between studied vegetal samples given by analysis.
In my first book, published in 1962, I quoted discrepancies in
the atomic mass of K measured with a mass spectrometer in
potatoes. The mass varied according to the variety. These
variations were not mentioned because they were attributed to
errors in the laboratory procedure. Any other explanation
could not be believed.

Too many physicists and in their lead,
phytobiologists, chemical physicists, medical doctors,
agronomists and others, still ignored at this date these ideas
seldom taught in school. For them, the isotopic composition is
stable and the atomic mass is given in chemical tables.

For how many physicists, even nuclear
physicists, this axiom has become a taboo. Some told me, "Your
reactions will only be accepted when you show that initial
isotopes correspond quantitatively to final isotopes". To
illustrate their point, according to them the increase in Ca
in a plant must represent the sum of an atom of K and an atom
of H, such that K39 + H1 >> Ca40
or K41 + H1 >> Ca42.
There is very little heavy hydrogen (deuterium) and it can be
neglected usually. However it is not always the case. It is
obvious that all the stable isotopes of Ca cannot be derived
from the stable isotopes of K and H. I will state again that
so far I never observed that Nature had to start from
radioactive isotopes and that it could not produce radioactive
elements. I do not pretend that it is not so and I insist on
this point: I never observed it personally. Studies were made
on this subject with extremely sensitive instruments, as at
the French Centre dEtudes Nucleaires in Saclay. Hence it was
proved that the N15 + O16 >> P31
reaction by microbial action could only be obtained from N15
and O16, and that all other P isotopes would be
unstable and radioactive.

All radioactive isotopes found in living matter
come from the outside, as it is the case in particular for C14
and K40; furthermore they are found there in
microscopic doses. A complete study of these cases must still
be made as they occur during germination. I lacked the time
and the financial resources required for such a study.

Studies made on K and Ca isotopes show that the
isotopic composition of a plant is different from the isotopic
composition of a seed from which it originated. Photosynthesis
should be kept in mind. We saw that it may vary according to
the photosynthesis cycle specific to the vegetal family. This
is why we can state that the people, who misinterpret the
quantitative inequalities between isotopes in biological
transmutations, make unwarranted generalizations. This should
not be construed as a weak point in my observations, but only
as the proof of their ignorance.

One should also keeping mind what I stated in my
earlier books and what I summarized in my book of 1975. All
the Ca does not come from an agglomeration, from a fusion of K
and H. there are other sources which vary according to the
calcicole or calcifuge character of the plant. Specific
species may need an alkaline, acid or neutral soil. A legume
is not cultivated as rye grass or oats. Some plant families
can transform manganese into iron. The reaction may be
reversed in other plants and in other soils. The reaction is
as follows: Mn55 + H1 >> Fe56.
In animals the following reactions occur frequently Mg24
+ O16 >> Ca40. The various stable
isotopes of Mg and O correspond to stable Ca isotopes. Other
stable Ca isotopes may lead to think that they come from
stable silicon and carbon isotopes. I dedicated several
chapters to these transmutations in my earlier books. I noted
that in 1799 Vauquelin suspected such a correlation, although
he did not mention it. Nuclear questions were unknown at the
time. His chemical analyses showed an increase in Ca and a
decrease in Si which were not quantitatively equivalent. He
could not have thought of the K + H transmutation. I did not
have the time to investigate the various potential origins of
the Ca. Simplifications are out of the question and
generalizations even more so. Naturally Vauquelin could not
introduce isotopes in his comparisons, as the isotope concept
was totally unknown at the time.

I also showed the isotopic correlation Fe56
- He4 >> Cr52 which is valid for
the four stable isotopes of Fe and Cr. He4 is the
alpha particle. The correlation holds also to the few
thousandths for the ratios between stable isotopes. I
discussed this point in particular in my last two books. One
should keep in mind this neutronic activation property. Its
concept is completely ignored, even rejected with contempt, by
many specialists. For them there are no differences in the
compositions of live and dead matters. Life can only engage in
chemistry, in which discipline nothing is lost and nothing is
created. However, there is an indisputable variation during
germination, as we showed in the first part of this book. We
proved that the creation of Ca in oat after germination in a
medium which could not receive any calcium from the outside.
To compute the total Ca weight according to the isotopic ratio
for a specific nucleus may seem to be a figment of the mind.
However, one should not forget that the isotopic compositions
given in the Atomic Mass Tables used in chemistry appeared to
be so different from each other that it was necessary to
define internationally the origin of the element selected as
isotopic composition standard. Discrepancies are often greater
than 1/1,000. In some cases they can be much greater, for the
deuterium/light hydrogen ratio, for example, because the
deuterium atomic mass is nearly the double of atomic mass of
light hydrogen. In some reactions, decreases of up to 70% in H
were noted compared to the initial isotopic mixture. This is
the phenomenon which allowed isotopic enrichments by
separation of light and heavy isotopes. This separation can be
obtained kinematically by diffusion through the appropriately
calibrated hole of a porous membrane. There is no
transmutation in this case, but obviously one should have some
reservation regarding some methods used to track Ca or other
elements, by neutronic activation for example. This does not
mean that this technique should be absolutely rejected from
the outset, but that the results must be cross-checked
whenever the analysis is performed on living material. By
neutronic activation the stable Ca48 becomes radioactive Ca 49
which is easily identified with accuracy. It seems that the
ratios between these two Ca isotopes and the total Ca remains
constant in the seeds as well as in the plants. It is
therefore possible to use them to measure the total Ca.
However, this does not explain the origin of Ca42
in the total Ca in live materials. One should remember that
there is only 0.18.1,000 (less than 0.3/1,000) of Ca48
in the standard. This extremely small concentration can only
be marginally detected by many analytical techniques. This may
be one reason why it is so difficult to trace the origin of
this isotope. In oats its concentrations increase from the
seed to the plant. Whatever happens, it is accepted that the
Ca48/total Ca remains approximately constant. Total
Ca variation is computed according to the variation in
activated Ca.

In this regard the director of a neutronic
activation analysis laboratory wrote to me in February 1976:

"We measure the Ca coming from the Ca48
>> Ca47 reaction. Therefore the activation
analysis yields basically the amount of Ca. The total Ca is
obtained by accepting (assuming) the natural distribution of
isotopes".

For many physicists this acceptance is still an
act of faith at the present day. There can be exceptions,
though this is not obvious, as I and many others before me
could observe it. However results obtained by the neutronic
activation technique should never be accepted blindly; they
should always be cross-checked by chemical analysis (a
gravimetric technique in particular). Sometimes I have another
cross-check made by atomic absorption spectrophotometry (with
a Beckman or Perkin-Elmer instrument).

Macroscopically the question of the origin of
the Ca isotope is unimportant, because this element represents
only 2/1,000 of the total. However, I do not underestimate the
theoretical importance it may represent and it is the reason
why I discussed it here, so physicists would not forget,
sometimes willfully, or would not ignore the biological causes
of some physical phenomena, among them the isotopic
selectivity of live materials.

**(2) Nature Operates at a Finer Level than Man
~**

How much progress was achieved in chemistry in
the last 100 years! It is now to the point that chemistry
invades everything, that all products on the market owe their
existence to chemistry and very few products are natural
anymore. Unfortunately there are people who do not understand
that this ingestion of chemical products damages our bodies.

People who are for the use of chemical products
pretend that natural and synthetic chemical products of the
same formula have the same effects on the human body. They
state that their effects on our body are necessarily the same,
because they cannot be discriminated a=from the chemical point
of view, and for them al of Life phenomena are chemistry.

It is their mistake. Chemical analysis is not
enough to characterize a product. As a matter of fact,
biochemists agree on this point now. They know that
qualitatively and quantitatively identical atoms can be
located in space in different ways, and that for this reason,
resulting external electron envelopes may be different.

---

**Translation ends here. The following sections
are not available in English (or perhaps my photocopy was
incomplete):**

**...(4) Changes in our understanding of some
aspects of physics and weakness of this understanding ~ (5)
A few arguments against a unified theory for electromagnetic
and weak interactions ~ (6) Intermediary vector bosons**

**Appendix 1 ~ Geology**

**Appendix II ~ An Extrapolation: (1) Crying
wolf ~ (2) One must rethink the concept of energy in living
matter ~ (3) Non-electromagnetic energies in living matter ~
(4) Parapsychology and hypothalamus ~ (5) Germination
procedure for oat seeds with no external addition of calcium**

**Appendix III ~ Weinberg Theory Summary: A few
definitions**

**Bibliography**

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