D. Mendeleef: A Chemical Conception of the Aether

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**D. MENDELEEF**

**Aether**

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***An Attempt Towards
A Chemical Conception Of The Ether***

by **Professor D. Mendeleeff**

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Translated from the Russian by George Kamensky (Imperial Mint,
St. Petersburg)

Longmans, Green & Co, NY (1904)

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In his *Dictionaire Complet*, P. Larousse defines the
ether as an imponderable elastic fluid, filling space and
forming the source of light, heat, electricity, etc. This is
laconic, but sufficient to raise some misgivings in the mind of
a thoughtful man of science. He is obliged to admit, in the
ether, the properties of a substance (fluid), while at the same
time, in order to explain in some way the transmission of energy
through space by its motion, the ether is assumed to be an
all-pervading medium. Moreover, in order to explain the
phenomena of light, electricity, and even gravity, this medium
is supposed to undergo various disturbances (perturbations) and
changes in its structure (deformation), like those observed in
solids, liquids and gases. If the fluid medium permeates
everything and everywhere, it cannot be said to have weight,
just as the ponderability of air could not be recognized before
the invention of the air pump. Yet the ether must have weight,
because, since the days of Galileo and Newton, the quality of
gravitation or of weight forms a primary property of substances.
From various considerations Lord Kelvin came to the conclusion
that a cubic meter of ether should weigh about and not less than
0.000,000,000,000,000,1 gram, while a cubic meter of the
lightest gas, hydrogen, weighs 90 grams under the atmospheric
pressure. The above-mentioned misgivings of the thoughtful
scientist in his most plausible endeavors to ascribe a certain
weight or mass to the ether, for the question naturally arises:
At what pressure and temperature will this weight be proper to
ether? For at infinitely small pressures or exceedingly high
temperatures steam or hydrogen would have as small a density as
that given by Lord Kelvin for the ether. And as regards the
density of the ether in interplanetary space, neither steam nor
hydrogen would have a measurable density in these regions,
notwithstanding the extreme cold, for the pressure would be
infinitely small. Theoretically, space may be supposed to be
filled with such rarified residues of vapors and gases. And this
view even corresponds with Kants and LaPlaces and other
theories, which strive to explain the unity of plan in the
creation of the heavenly bodies. It also accounts for the
uniformity of the chemical composition of the entire universe,
demonstrated by the spectroscope, as it gives a means, through
the agency of such ether, of interchange between the heavenly
bodies. One of the objects of an investigation into the
elasticity or compressibility of gases under low pressure,
undertaken by me in the 1870s, was to trace, as far as the then
existing methods of measuring low pressures permitted, the
changes proceeding in gases under low pressures. The
discrepancies from Boyles law observed (by me and M.
Kirpitchnikoff, 1874) for all gases, and subsequently confirmed
by Ramsay and others (although still denied by some
investigators), indicate a certain uniformity in the behavior of
all gases and a tendency in them towards a certain limiting
expansion at low pressures, just as there is a limit to
compression (liquefaction and the critical state). But
determinations of very low pressures are accompanied by
insurmountable difficulties. It proved practically impossible to
measure, with any degree of accuracy, pressures under tenths of
a millimeter of mercury, and this is far too large a figure for
such rarified media as are supposed to exist at an elevation of
even 50 kilometers above sea level. Hence the conception of the
ether as a highly rarified atmospheric gas cannot so far be
subjected to experimental investigation and measurement, which
alone can direct the mind in the right direction and lead to
reliable results.

But, beyond this, the conception of the ether as a limiting
state of expansion of vapors and gases cannot sustain even the
most elementary analysis, for ether cannot be understood
otherwise than as an all-pervading ubiquitous substance, and
this is not the property of either gases or vapors. Both the
latter are liquefiable under pressure, and cannot be said to
permeate all substances, although they are widely distributed in
mature, even in meteorites. Moreover -- and this is the most
important -- they vary infinitely in their chemical nature and
in their relations to other substances, while the ether, as far
as is known, is invariable. Owing to the variety of their
chemical properties, all vapors and gases should react
differently on the bodies which they permeate if they were
components of the ether.

Before proceeding further, I think it necessary to justify the
chemical views here and elsewhere brought into play. In the days
of Galileo and Newton it was possible, although difficult, to
conceive ether apart from them. But now it would be contrary to
the most fundamental principles of natural science, for
chemistry, since Lavoisier, Dalton and Avogadro Gerhardt, has
acquired the most sacred rights of citizenship in the great
company of the natural sciences, and by placing the mass
(weight) of a substance among its paramount conceptions it has
followed the path indicated by Galileo and Newton. Moreover,
chemistry and its methods alone have promoted in science a
desire to apprehend bodies and their phenomena in their ultimate
relations, through a conception of the reaction of their
infinitely small parts or atoms which may in fact be regarded as
indivisible individuals, having nothing in common with the
mechanically indivisible atoms of the ancient metaphysicians.
There are many proofs of this; it will suffice to mention the
fact that the atoms of modern science have often been explained
by vortex rings, that there was formerly a strong inclination to
conceive the chemical atoms as built up of themselves, or of a
primary matter, and that recently, especially in speaking of
the radioactive substances, a division of chemical atoms into
yet smaller electrons begins to be recognized; all of which
would be logically impossible were the atom regarded as
mechanically indivisible. Chemically the atoms may be likened to
the heavenly bodies, the stars, sun, planets, satellites,
comets, &c. The building up of molecules from atoms, and of
substances from molecules, is then conceived to resemble the
building up of systems, such as the solar system, or that of
twin stars or constellations, from these individual bodies. This
is not a simple play of words in modern chemistry, nor a mere
analogy, but a reality which directs the course of all chemical
research, analysis, and synthesis. Chemistry has its own
microscope for investigating invisible regions, and being an
archi-real science it deals all the time with its invisible
individualities without considering them mechanically
indivisible. The atoms and molecules which are dealt with in all
provinces of modern mechanics and physics cannot be other than
the atoms and molecules defined by chemistry, for this is
required by the unity of science. And therefore the
metaphysicians of the present day should, for the advancement of
knowledge, regard atoms in the same sense as that in which they
are understood by natural science and not after the manner of
the ancient metaphysicians of the Chinese or Greek schools. If
the Newtonian theory of gravity revealed the existence of forces
acting at infinitely great distances, the chemistry of
Lavoisier, Dalton and Avogadro Gerhardt, on the other hand,
disclosed the existence of forces of immense power acting at
infinitely small distances, and transmutable into all other
forms of energy, mechanical and physical. Thus all the
present-day fundamental conceptions of natural science -- and
consequently the conception of the ether -- must necessarily be
considered under the combined influence of chemical, physical,
and mechanical teachings. Although skeptical indifference is
prone to discern only a working hypothesis in the conception
of the ether, yet the earnest investigator, seeking the reality
of truth, and not the image of fantasy, is forced to ask himself
what is the chemical nature of the ether.

Before endeavoring to give an answer respecting the chemical
nature of ether, I think it necessary to state my opinion
regarding the belief held by some in the unity of the substance
of the chemical elements and their origin from one primary form
of matter. According to this view, ether consists of this
primary matter in an unassociated form, that is, not in the form
of the elementary atoms or molecules of substances, but as the
constituent principle out of which the chemical atoms are
formed. This view has much that is attractive. The atoms are
regarded as proceeding from primary matter in the same way as
celestial bodies are sometimes represented as being formed from
disunited bodies, such as cosmic dust, etc. The celestial bodies
so formed remain surrounded by the cosmic dust, etc., from which
they took their origin. So also the atoms remain in the midst of
the all-pervading and primary ether from which they took their
origin. Some persons assume also that atoms can be split up into
their dust or primary matter, just as comets break up into
falling stars; and that, as the geological changes of the earth
or the building up and dissociation of heavenly bodies proceed
before our eyes, so also do the atoms break up and form again in
the silence of their eternal evolution. Others, without denying
the possibility of such a process in the exceptional rare cases,
consider the world of atoms to have been established once for
all, and do not admit the possibility of decomposing the atom
into its primary matter, or of forming new atoms of any chemical
element from this primary matter by experimental means. In a
word, they regard the process of the creation of atoms as finite
and not subject to repetition, while they consider the ether as
the residue remaining after the formation of atoms. This view
need not be considered here, it being solely the fruit of
imagination and unproved by any experimental investigation. But
the former theory of a progressive evolution of the substance of
atoms cannot be passed unnoticed by chemistry, for fundamental
principles of this science are the indestructibility of matter
and the immutability of the atoms forming the elements. If ether
were producible fro atoms and atoms could be built up from
ether, the formation of new unlooked-for atoms and the
disappearance of portions of the elements during experiment
would be possible. A belief in such a possibility has long been
held in the minds of may by force of superstition; and the more
recent researches of Emmens to convert silver into gold, and
those of Fittica (1900) to prove that phosphorus can be
converted into arsenic, show that it yet exists. In the 50 years
during which I have carefully followed the records of chemistry,
I have met with many such instances, but they have always proved
unfounded. It is not my purpose here to defend the independent
individuality of the chemical elements, but I am forced to refer
to it in speaking of the ether, for it seems to me that, besides
being chemically invalid, it is impossible to conceive of an
ether as a primary substance, because such a substance should
have some mass or weight and also chemical relations -- mass in
order to explain the majority of phenomena proceeding at all
distances up to the infinitely great, and chemical relations in
order to explain those proceeding at distances infinitely small
or commensurable with the atoms. If the question were restricted
to the ether which fills space and serves as a medium for the
transmission of energy, it would in a way be possible to limit
oneself to the supposition of mass without reference to its
chemical relations and even to consider the ether as a primary
matter, Justas the mass of a planet may be conceived without
regarding its chemical composition. But such an indifferent,
indefinite ether loses all sense of reality and awakens the
misgivings of the earnest investigator, directly he realizes
that it must permeate all substances. The necessity I an easy
and perfect permeation of all bodies by the ether has to be
admitted, not only for the comprehension of many physical
phenomena (such as those o optics), but also owing to the great
elasticity and rarity of the ethereal substance, the atoms of
which are always conceived a being far more minute than the
atoms and molecules of the known chemical substances. Moreover,
this permeability of ether I all bodies explains why it cannot
be isolated from substances, which indeed behave in respect to
ether like a sieve to water or air. The capacity of the ether to
penetrate all substances may, however, be regarded as the ideal
of the diffusion of gases through metals and other diaphragms.
Hydrogen, which ha a small atomic weight and is the lightest of
all known gases, not only diffuses more rapidly than any other
gas, but also has the faculty of penetrating through walls of
such metals as platinum and palladium, which are impervious to
other gases. This property is due, not only to the rapidity of
motion of the molecules of hydrogen, closely connected with its
small density, but also to a chemical faculty of the same kind
as exhibited in the formation of metallic hydrides, of
solutions, alloys and other indefinite compounds. The mechanism
of this penetration may be likened (at the surface of the body
penetrated) to the solution of a gas in a liquid, that is, to
the gaseous particles leaping into the interstices between the
particles of the liquid with a retardation of their motion (a
partial liquefaction of the gas) and a bringing into harmony of
the motion of both kinds of particles. The condensed gas
absorbed at the surface of contact travels in all directions
through the body, and diffuses from one layer to another until
it entirely permeates it. The possibility of gaseous hydrogen
acting thus is evident from the fact that even gold diffuses
through solid lead under the same force. At length, at the
opposite surface of the body penetrated, the condensed gas will
find it possible to escape into greater freedom, and will
continue to pass in this direction until its degree of
concentration becomes the same on both sides. When this takes
place it does not set up a sate of rest, but one of mobile
equilibrium, that is, equal numbers of molecules or atoms will
escape and leap in at both sides. If, as it must, ether has the
faculty of permeating all substances, it must be even lighter
and more elastic (greater vis viva) than hydrogen, and, what is
most important, must have less capacity than hydrogen to form
chemical compounds with the bodies it permeates. Compounds are
characterized by the fact that the diverse atoms in them form
systems or molecules, in which the different elements are in
compatible, harmonious motion. We must therefore suppose that
such a state of harmonious motion of, for instance, hydrogen and
palladium, is actually set up in those atoms of hydrogen which
permeate the palladium, and that in so doing it forms with the
palladium some compound (either Pd2H or another)
which easily dissociates when heated. Hence it seems to me that
the atoms of ether are so void of this faculty of forming
compounds (which is already weak in hydrogen) that such
compounds dissociate at all temperatures, and that therefore
nothing beyond a certain condensation among the atoms of
substances can be looked for in the ether.

Eight years ago, it would have been most arbitrary to deny the
existence, in the substance or atoms of ether, of the faculty of
forming any compounds with their chemical elements, for in those
days all the known elements were, directly or indirectly,
capable of entering into mutual combination. But in 1894 Lord
Rayleigh and Professor Ramsay discovered argon, and defined it
as the most inactive element; this was followed by the discovery
of helium, the existence of which Lockyer had predicted by its
spectrum as a solar element, and subsequently by the separation
of neon, krypton and xenon from air. None of these five new
gases have yet given any definite compounds, although they
clearly evince the faculty of solution, i.e., of forming
definite, easily dissociated compounds. Thus we have now every
right to say that the ether is unable to form any stable
compounds with other chemical atoms, although it permeates all
substances.

Hence *the ether may be said to be a gas, like helium or
argon, incapable of chemical combination*. This definition
of the ether as a gas, signifies that it belongs to the category
of the ordinary physical states of matter, gaseous, liquid or
solid. It does not require the recognition of a peculiar fourth
state beyond the human understanding (Crookes). All mystical,
spiritual ideas about ether disappear. In calling ether a gas,
we understand a fluid in the widest sense; an elastic fluid
having no cohesion between its parts. Furthermore, if ether be a
gas, it has weight; this is undisputable, unless the whole
essence of natural science, from the days of Galileo, Newton,
and Lavoisier, be discarded for its sake. But since ether
possesses so great a penetrative power that it passes through
every envelope, it is, of course, impossible to experimentally
determine its mass in a given amount o other substances, or the
weight of a given volume of ether. We ought, therefore, not to
speak of the imponderability of ether, but only of the
impossibility of weighing it.

The preceding remarks are in exact accordance with the
generally accepted conception of ether. The only addition made
is to ascribe to ether the properties of a gas, like argon and
helium utterly incapable of entering into true chemical
combination. This point lies at the basis of our investigation
into the chemical nature of ether, and includes the following
two fundamental propositions: (1), that the ether is the
lightest (in this respect ultimate) gas, and is endowed with a
high penetrating power, which signifies that its particles have,
relatively to other gases, small weight and extremely high
velocity, and (2), that ether is a simple body (element)
incapable of entering into combination or reaction with other
elements or compounds, although capable of penetrating their
substance, just as helium, argon, and their analogues are
soluble in water and other liquids.

The argon group of gases and the periodic system o the elements
have such a close bearing upon our further consideration of the
chemical nature of ether that it behooves us to look at them
more closely.

When in 1869 I first showed the periodic dependence of the
properties of the elements upon their atomic weights, no element
incapable of forming definite compounds was known, nor was the
existence of such an element even suspected. Therefore the
periodic system was arranged by me in groups, series, and
periods, starting with group I and series I, with hydrogen as
the lightest and least dense of all the elements. It never
occurred to me that hydrogen might be the starting point of a
system of elements. Guided by this system, I was able to predict
both the existence of several unknown elements and also their
physical and chemical properties in a free and combined state.
These elements, gallium, scandium, and germanium, were
subsequently discovered by Lecoq de Boisbaudran, Nilson, and
Winkler respectively. I made these predictions by following what
is known in mathematics as a method of interpolation, that is,
by finding intermediate points by means of two extreme points
whose relative position is known. The fact of my predictions
having proved true confirmed the periodic system of elements,
which may now be considered as an absolute law. So long as the
law remained unconfirmed, it was not possible to extrapolate
(i.e., to determine points beyond the limits of the known) by
its means, but now such a method may be followed, and I have
ventured to do so in the following remarks on the ether, as an
element lighter than hydrogen. My reason for doing this was
determined by two considerations. In the first place, I think I
have not many years for delay; and, in the second place, in
recent years there has been much talk about the division of
atoms into more minute electrons, and it seems to me that such
ideas are not so much metaphysical as metachemical, proceeding
form the absence of any definite notions upon the chemism of
ether, and it is my desire to replace such vague ideas by a more
real notion of the chemical nature of the ether. For until some
one demonstrates either the actual transformation of ordinary
matter into ether, or the reverse, or else the transformation of
one element into another, I consider that any conception of the
division of atoms is contrary to the scientific teaching of the
present day; and that those phenomena in which a division of
atoms is recognized would be better understood as a separation
or emission of the generally recognized and all-permeating
ether. In a word, it seems to me that the time has arrived to
speak of the chemical nature of the ether, all the more so
since, so far as I know, no one has spoken at all definitely on
this subject. When I applied the periodic law to the analogs of
boron, aluminum, and silicon, I was 33 years younger than now,
and I was perfectly confident that sooner or later my prediction
would be fulfilled. Now I see less clearly and my confidence is
not so great. Then I risked nothing, now I do. This required
some courage, which I acquired when I saw the phenomena of
radioactivity. I the saw that I must not delay, that perhaps my
imperfect thoughts might lead some one to a surer path than that
which was opened to my enfeebled vision.

First, I will treat of the position of helium, argon, and their
analogs in the periodic system; then of the position of ether I
this system; and conclude with some remarks on the probable
properties of ether according to the position it occupies in the
periodic system.

When, in 1895, I first heard of argon and its great chemical
inertness, I doubted the elementary nature of the gas, and
thought it might be a polymeride of nitrogen, N3,
just as ozone, O3, is a polymeride of oxygen, with
the difference that, while ozone is formed from oxygen with the
absorption of heat, argon might be regarded as nitrogen deprived
of heat. In chemistry nitrogen was always regarded as the type
of chemical inertness, i.e., of an element which enters into
reaction with great difficulty, and if its atoms lost heat in
becoming condensed by polymerization from N2 to N3,
it would form a still less active body; just as silica, which is
formed from silicon and oxygen with the evolution of heat, is
more inert than either of them separately. Berthelot
subsequently published a similar view on the nature of argon,
but I have now long discarded that and consider argon to be an
independent element, as Ramsay held it to be from the very
beginning. Many reasons induced me to adopt this view, and
chiefly the facts that (1) the density of argon is certainly
much below 21, namely about 19, that of H being 1, while the
density of N3 would be about 21, for the molecular
density of N3 = 14 x 3 = 42 and the density would be
half this; (2) helium, discovered by Ramsay in 1895, has a
density of about 2 referred to hydrogen, and exhibits the same
chemical inactivity as argon, and in its case this inactivity
can certainly not be due to a complexity of its molecule; (3) in
their newly discovered neon, krypton, and xenon, Ramsay and
Travers found a similar inactivity which, in these cases also,
could not be explained by polymerization; (4) the independent
nature of the separate spectra of these gases, and the
invariability of these spectra under the influence of electric
sparks, proved that they belong to a family of elementary gases
different from all other elements, and (5) the graduation and
definite character of the physical properties in dependence upon
the density and atomic weight further confirm the fact of their
being simple bodies, whose individuality, in the absence of
chemical reactions, can only be affirmed from the constancy of
their physical features. An instance of this is seen in the
boiling points (at 760 mm) or temperatures at which the vapor
pressures equal the atmospheric pressure and at which the liquid
and gaseous phases are co-existent:

                                       
He       
Ne     
Ar        
Kr        
Xe
  
Atomic
weight:                 
4        
19.9    
38        
81.8    
128
  
Observed
density:            
2        
9.95    
18.8     
40.6     63.5   
Observed boiling point:    
-262     -239   
-187     -152     -100

This recalls the halogen group:

                              
F        
Cl        
Br        
I   
Mol.
Weight:          
38      
79.9     159.9     254   
Vapor density:        
19      
35.5    
80         127   
Boiling
point           
-187    -34    
+57.7     +183.7

In both cases the boiling point clearly rises with the atomic
or molecular weight. When the elementary nature of the argon
analogs and their characteristic chemical inactivity were once
proved, it became essential that they should take their place in
the periodic system of the elements; not in any of the known
groups but in a special one of their own, for they exhibited
new, hitherto unknown chemical properties, and the periodic
system embraces in different groups those elements which are
analogous in their fundamental chemical properties, although not
in dependence upon these properties but upon their atomic
weight, which apparently -- previous to the discovery of the
periodic law -- stands in no direct relation to these
properties. This was a critical test for the periodic law and
the analogs of argon, but they both stood the test with perfect
success; that is, the atomic weights, calculated from the
observed densities, proved to be in perfect accordance with the
periodic law.

Although I assume that the reader is acquainted with the
periodic law, yet it may be well to mention that if the elements
be arranged in the order of their atomic weights it will be
found that similar variations in their chemical properties
repeat themselves periodically, and that the order of the
faculty of the elements to combine with other elements also
corresponds with the order of their atomic weights. This is seen
in the following simple example.

All the elements having an atomic weight of not less than 7 and
not more than 85.5 fall into two series:

Li = 7.0  ~  Be = 9.1  ~  B = 11.0 
~  C = 12.0  ~  N = 14.0  ~  O =
16  ~  F = 19.0 ~   
Na = 23.0  ~  Mg = 24.3  ~  Al = 27.0 
~  Si = 28.4  ~  P = 31.0  ~  S =
32.1  ~  Cl = 35.5

Each pair of elements present a great similarity in their chief
properties; this is especially marked in the higher saline
oxides, which in the lower series are:

Na2O ~ MgO ~ Al2O3 ~ SiO2 ~ P2O5
~ SO3 ~ Cl2O7, or   
Na2O, Mg2O2, Al2O3,
Si2O4, P2O5, S2O6,
Cl2O7.

Thus the atomic order of the elements exactly corresponds to
the arithmetical order from 1 to 7. So that the groups of the
analogous elements may be designated by the Roman ciphers I to
VII: and when it is said that phosphorus belongs to Group V, it
signifies that it forms a higher saline oxide P2O5.
And if the analogs of argon do not form any compounds of any
kind, it is evident that they cannot be included in any of the
groups of the previously known elements, but should form a
special zero group which at once expresses the fact of their
chemical indifference. Moreover, their atomic weight should
necessarily be less than those of group I: Li, Na, K, Rd, and
Cs, but greater than those of the halogens, F, Cl, Br and I, and
this a priori conclusion was subsequently confirmed by fact,
thus:

Halogens         Argon
analogs     Alkali metals   
                      
He
=
4.0             
Li
= 7.03   
F =
19           
Ne =
19.9           
Na = 23.05   
Cl = 35.5        Ar =
38               
K
= 39.1   
Br = 79.95      Kr =
81.8           
Rh = 85.4   
I =
127           
Xe =
128           
Cs = 132.9

The five well-known alkali metals correspond to the newly
discovered argon analogs, and the atomic weights of both exhibit
the same common law of periodicity. But the halogens and alkali
metals are the most chemically active among the elements, and
are, moreover, of opposite chemical nature, the first being
particularly prone to react with metals and the others with
metalloids, the former appearing at the anode and the latter at
the cathode. They must therefore stand at the two extremes of
the periodic system, as in the scheme in **Figure 1**.

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**Figure 1**

![](ptable1.jpg)

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Although this arrangement best expresses the periodic law, the
distribution of the elements according to groups and series in
the table of **Figure 2** is perhaps clearer:

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**Figure 2**

![](ptable2a.jpg)

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Here *x* and *y* stand for two unknown elements
having atomic weights less than that of hydrogen, whose
discovery I now look for.

A reference to the above remarks on the argon group of elements
shows first of all that such a zero group as they correspond to
could not possibly have been foreseen under the conditions of
chemical knowledge at the time of the discovery of the periodic
law in 1869; and, although I had a vague notion that hydrogen
might be preceded by some elements of less atomic weight, I
dared not put forward such a proposal, because it was purely
conjectural, and I feared to injure the first impression of the
periodic law by its introduction. Moreover, in those days the
question of the ether did not awaken much interest, for
electrical phenomena were not then ascribed to its agency, and
it is this that now gives such importance to the ether. But at
the present time, when there can be no doubt that the hydrogen
group is preceded by the zero group composed of elements of less
atomic weights, it seems to me impossible to deny the existence
of elements lighter than hydrogen.

Let us first consider the element in the first series of the
zero group. It is designated by *y*. It will evidently
exhibit all the fundamental properties of the argon gases. But
first we must have an approximate idea of its atomic weight. To
do this, let us consider the ratio of the atomic weights of two
elements belonging to the same group in the neighboring series.
Starting with Ce = 140 and Sn = 119 (here the ratio is 1.18),
this ratio, in passing to the lower groups and series, increases
constantly and fairly uniformly as the atomic weights of the
elements under comparison decrease. But we will limit our
calculation to the first and second series, starting with Cl =
85.45; for (1) we are exclusively concerned wit the lightest
elements, (2) the ratio of the atomic weights is more accurate
for these elements, and (3) the small periods of the typical
elements (which should include the elements lighter than
hydrogen) terminate with chlorine. As the atomic weight of
chlorine is 35.45 and that of fluorine 19.0, the ratio Cl:F =
35.4:19.0 = 1.86; so also we find:

Group   
VII     Cl:F = 1.86   
VI     S:O = 2.00   
V     P:N = 2.21   
IV     Si:C = 2.37   
III     Al:B = 2.45   
II     Mg:Be = 2.67   
I     Na:Li = 3.28   
0     Ne:He = 4.98

This proves that the ratio in the given series distinctly and
progressively increases in passing from the higher to the lower
groups; and, moreover, that it varies most rapidly between the
first and zero groups. It follows therefore that the ratio He:*y*
will be considerably greater than the ratio Li:H which is 6.97,
so that the ratio He:*y* will be at least 10 and probably
even greater. Hence, as the atomic ratio He = 4.0, the atomic
weight of *y* will not be greater than 4.0/10 = 0.4 and
probably less. Such an analog of helium may perhaps be founding
coronium, whose spectrum, clearly visible in the solar corona
above (that is, further from the sun than) that of hydrogen, is
simple like that of helium, which seems to indicate that it
belongs to a gas resembling helium, which was also predicted
from its spectrum by Lockyer. Young and Harkness independently
observed the spectrum of this unknown element during the solar
eclipse of 1869. It is characterized by a bright-green line at
531.7 uu, while helium is characterized by a yellow line, 587
uu. Nasini, Anderlini, and Salvadori think that they discovered
traces of coronium in their observations on the spectra of
volcanic gases (1893). And as the lines of coronium were also
observed, even at distances many times the radius of the sun
above its atmosphere and protuberances, where the hydrogen lines
are no longer visible, it is evident that coronium should have
less density and atomic weight than hydrogen. Moreover, as the
ratio of the specific heats (at a constant pressure and for a
constant volume) of helium, argon, and their analogs gives
reason for thinking that their molecules (i.e., the amount of
matter occupying, according to Avogadro-Gerhardts law, a volume
equal to the volume of two parts by weight of hydrogen) contain
only one atom  (like mercury, cadmium and most metals), it
follows that, if 0.4 be the greatest atomic weight of the
element *y*, its density referred to hydrogen should be
less than 0.2. Consequently the molecules of this gas will,
according to the kinetic theory of gases, move 2.24 times faster
than those of hydrogen, and if, as Stoney (1894-1898) and
Rostovsky (1899) endeavor to prove, the progressive motion of
the molecules of hydrogen and helium be such that they can leap
out of the sphere of earths attraction, then a gas whose
density is at least five times less than that of hydrogen could
certainly only exist in the atmosphere of a body having as great
a mass as the sun. However, this *y*-coronium or some
other gas with a density of about 0.2 cannot possibly be ether,
its density being too great. It wanders, perhaps for ages, in
the regions of space, breaks from the shackles of the earth and
again comes within its sphere, but still it cannot escape from
the regions of the suns attraction, and there are many heavenly
bodies of greater mass than the sun. But the atoms of ether must
be of another kind; they must be capable of overcoming even the
suns attraction, of freely permeating all space, and of
penetrating everything and everywhere. The element *y*,
however, is necessary for us to be able to mentally realize the
lightest and therefore swiftest element, *x*, which I
consider may be looked upon as the ether.

We have seen that, besides the ordinary groups of the
chemically active elements, a zero group of chemically inactive
elements must now be recognized for helium, argon, and their
analogs. Thanks to Ramsays exemplary researches, these elements
are now tangible realities, authentic gases foreign to chemical
association, that is, distinguished by their specific property
of not being chemically attracted to each other or to other
atoms even at infinitely small distances, and yet having weight,
that is, subject to the law of attraction of mechanics, which
has nothing in common with chemical attraction. There is some
hope that gravity may in some way or another be explained by
means of pressure or impact acting from all sides, but chemical
attraction, which only acts at infinitely small distances, will
long remain an incomprehensible problem. The problem of the
ether is more or less closely connected with that of gravity,
and gains in simplicity when all question of the chemical
attraction of the atoms of ether is excluded, and this is
accomplished by placing it in the zero group. But if the series
of elements begins with series I containing hydrogen, the zero
group has no place for an element lighter than *y*, like
ether. I therefore add a zero series, besides a zero group, to
the periodic system, and place the element *x* in this
zero series, regarding it (1) as the lightest of all the
elements both in density and atomic weight; (2) as the most
mobile gas; (3) as the element least prone to enter into
combination with other atoms, and (4) as an all-permeating and
penetrating substance. Of course, this is a hypothesis, but it
is not one constructed for purely working ends, but simply
from a desire to extend the real periodic system of the known
elements to the confines or limits of the lowest dimensions of
atoms, which I cannot and will not regard in the light of simple
nullity called mass.

Being unable to conceive the formation of the known elements
from hydrogen, I can neither regard them as being formed from
the element *x*, although it is the lightest of all the
elements. I cannot admit this, not only because no fact points
to the possibility of the transformation of one element into
another, but chiefly because I do not see that such an admission
would in any way facilitate or simplify our understanding of the
substances and phenomena of nature. And when I am told that the
doctrine of unity in the material of which the elements are
built up responds to an aspiration for unity in all things, I
can only reply that at the root of all things a distinction must
be made between matter, force, and mind; that it is simpler to
admit the germs of individuality in the material elements than
elsewhere, and that no general relation is possible between
things unless they have some individual character resident in
them. In a word, I see no object in following the doctrine of
unity of matter, while I clearly see the necessity of
recognizing the unity of the substance of ether and of realizing
a conception of it, as the uttermost limit of that process by
which all the other atoms of the elements were formed and by
which all substances were formed from these atoms. To me this
kind of unity is far more real than any conception of the
formation of the elements from a single primary matter. Neither
gravity nor any of the problems of energy can be rightly
understood without a real conception of the ether as a universal
medium transmitting energy at a distance. Moreover, a real
conception of ether cannot be obtained without recognizing its
chemical nature as an elementary substance, and in these days no
elementary substance is conceivable which is not subject to the
periodic law.

I will therefore, in conclusion, endeavor to show what
consequences should follow from the above conception of the
ether, from an experimental or realistic point of view, even
should it never be possible to isolate or combine or in any way
grasp this substance.

Although it was possible to approximately determine the atomic
weight of the element *y* on the basis of that of helium,
this cannot be repeated for the element *x*, because it
lies at the frontier or limit, about the zero point of the
atomic weights. Moreover, the analogs of helium cannot serve as
a basis owing to the uncertainty of their numerical data.
However, if the ratio of the atomic weights be Xe:Kr = 1.56:1;
Kr:Ar = 2.15:1, and Ar:He = 9.5:1, we find that He:*x* =
23.1:1, or if He = 4.9, that the atomic weight of *x* =
0.17. This must be considered the maximum possible value. Most
probably the atomic weight of *x* is far less, for the
following reasons. If the gas in question be an analog of
helium, its molecule will contain one atom, and therefore its
density, referred to that of hydrogen, must be about half its
atomic weight or *x*/2, where *x* is the atomic
weight. In order to be able to permeate throughout all space,
its density must be so small, compared with that of hydrogen,
that its molecular motion would allow it to overcome the
attraction, not only of the earth and sun, but also of all the
stars, as otherwise it would accumulate about the largest mass
and not fill all space. The velocity of the molecular motion is
determined by the number of impinging particles and their *vis
viva* is calculated according to the kinetic theory of
gases, by an expression containing a constant divided by the
square root of the density of the gas and multiplied by the
square root of (1 + *at*), which expresses the expansion
of the gas by heat. In the case of hydrogen (density = 1) at *t*
= 0 deg, the mean velocity of the particles, calculated on the
basis that a liter of hydrogen at 0 deg and 760 mm weighs bout 0.09
grams, is 1843 meters/second, that of oxygen being 461 meters,
for its density is 16 times that of hydrogen, i.e., *v* =
1843 / 4 = 461. Thus the velocity increases as the density
becomes less and as the temperature becomes greater, but does
not depend upon the number of molecules in a given volume; and
if our gas have an atomic weight *x* and density (referred
to hydrogen) *x*/2, then the velocity of its molecules
will be:

(I)     *v* = 1843 x sq. rt. 2(1 + *at*)/*x*

In this expression *x* is the unknown quantity, to find
which we must know *t* and *v*, or the velocity
required by the particles to escape from the sphere of the
earths suns and stars attraction, like the projectile in
Jules Vernes Voyage to the Moon.

As regards the temperature of space, this can only be regarded
as the absolute zero by those who deny the material nature of
the ether, for temperature in a perfect vacuum or I space devoid
of matter is an absurdity, and a solid such as an aerolite or
thermometer introduced into such space would alter the
temperature, not by contact with the surrounding medium, but
solely by radiation. But if space be filled with the substance
of ether, it not only may have, but must, have its own
temperature, which evidently cannot be absolute zero. Many
methods have been tried to determine this temperature, but it is
unnecessary to discuss them here. Suffice it to say that no one
has found it less than -150 deg or above -40 deg; as a rule, the
limits are taken as -100 deg and -60 deg. It is hopeless to expect any
definite or exact data on this subject, and probably the
temperature varies in different localities owing to radiation
being different in different parts of space. Moreover, the value
of *t* between -100 deg and -60 deg has hardly any significance
in an approximate evaluation of *x*, as only the maximum
value of *x* can be calculated by the expression (1); for
there can be no question of any exact value, all that is
required being to obtain an idea of the order in which *x*
stands among the elements. We therefore take *t* = -80;
then if *a* = 0.000367,

(II)     *v* = 2191 / sq. rt. *x*,
or *x* = 4800000/*v*2

where *x* is the atomic weight of the gaseous element
required, referred to hydrogen, and *v* the velocity of
motion of its particles at -80 deg in meters/second.

This velocity must now be determined. We know that a body
thrown up in the air falls back to earth, and in doing so
describes a parabola. The height of its flight increases as its
initial velocity is made greater, and it is evident that this
velocity might be such that the body would pass beyond the
sphere of the earths attraction, and fall on some other
heavenly body, or rotate about the earth as a satellite by
virtue of the laws of gravitation. It has been calculated that
to do this the velocity of the body must exceed the square root
of double the mass of the attracting body divided by the
distance from its center of gravity to the point at which the
velocity is determined. The mass of the earth is calculated in
absolute units from the mean radius of the earth ( = 6,373,000
meters) and the mean attraction of gravity at the surface of the
earth ( = 9.807 meters), for the attraction of gravity is equal
to the mass divided by the square of the distance (in this
instance, the square of the earths radius), and therefore the
mass of the earth -- 398.1012, and the velocity sought for must
therefore exceed 1,190 meters /second. Hence, according to
Formula II, the atomic weight of such a gas must be less than
0.038 to enable it to escape freely from the earths atmosphere
into space. All gases of greater atomic weight, not only
hydrogen and helium, but even the gas *y* (coronium?),
will remain in the earths atmosphere.

The mass of the sun is approximately 325,000, if that of the
earth is taken as unity. Hence the absolute magnitude of the
suns mass will be nearly 129.1018. The radius of the sun is
109.5 times greater than that of the earth, i.e., nearly
698.1016 meters. Hence only bodies or particles having a
velocity of about 608,300 meters/second could escape from the
surface of the sun. According to formula II, the atomic weight
of a gas *x* having such a velocity will not be half this
figure. Hence the atomic weight and density of such a gas which,
like the ether, permeates space, must at all events be less than
this figure. This is inevitable because there are stars of
greater mass than the sun. This has been proved by researches
made on double stars.

The most exact data we now possess concern Sirius, whose total
mass (including that of its satellites) is 3.24 times that of
the sun. To determine this, it was necessary to investigate not
only the relative motion of both stars, but also the parallax of
this system. In the case of Sirius it was possible to determine
the ratio of the masses of the two stars. This was found to be
2.05, so that the mass of one star is 2.20, and that of the
other 1.04 times that of the sun. In the following cases, only
the total mass of the two twin stars was determined relative to
that of the sun:

a-Centauri = 2.0   
70-Opiuchi = 1.6   
u-Cassiopeiae = 0.52   
61-Cygni = 0.34   
g-Leonus = 5.8   
g-Virginis = 32.7

The mass of B-Persei with its satellites is 0.67 times that of
the sun, that of the star being twice that of its satellite. The
triple star 40-Eridium has a mass 1.1 times that of the sun, the
mass of the brightest star being 2.37 times that of the other
two.

It appears, therefore, that although there are some stars which
are greater, and some which are less, still the mass of the sun
is nearly the average of that of the other stars. For our
purpose we need only consider the stars of much greater mass
than the sun. That of the double star g-Virginis has a common
mass about 33 times that of the sun. There is no reason for
thinking that this is the maximum, and it will therefore be
safer to infer that there may be stars whose mass exceed 50
times that of the sun, but I do not think it likely that a
larger mass than this is in the nature of things. To complete
our calculation it is also necessary to know the radius of the
stars, about which we have no direct data. However, the
composition and temperature of the stars may give a clue.
Spectrum analysis proves that the terrestrial chemical elements
occur in the most distant heavenly bodies, and from analogy
there seems no doubt that the general mass composition of these
bodies is very similar in all cases; that is to say, that they
are composed of a dense core surrounded by a less dense crust
and an atmosphere which becomes gradually rarefied. Thus the
composition of the stars probably differs but little from that
of the sun. Only at the core can the density differ much from
that of the sun, but this cannot greatly affect the average
density. Neither can the temperature of the stars differ greatly
from that of the sun. Moreover, a rise of temperature would tend
to increase the diameter of the star, and this would decrease
the value of the velocity required by the gaseous particles to
escape from the sphere of attraction. It appears, therefore,
that for the purposes of our calculation the average density of
the large stars may be taken as nearly that of the sun, and
therefore that the radius of a star whose mass is *n*
times that of the sun will be 3sq. rt. *n*
times the radius of the sun. We now have all the data necessary
for calculating the velocity required by gaseous particles to
escape from the sphere of attraction of a star 50 times greater
than the sun.

Its mass is 50.129.1018 or nearly 65.1029,
and its radius nearly 698.106.3 sq. rt. of 50, or
26.108. Hence the velocity required will be nearly
2,240,000 meters/second, or 2,240 kilometers/second.

The great magnitude of this velocity, *v*, and its
proximity to that of light (300,000,000 meters/second) provoke
the following inquiry. How much must the mass of a heavenly body
exceed that of the sun to retain on its surface particles
endowed with a velocity of 3.103 meters/second, if
its mean density were equal to that of the sun? This may be
calculated from the fact that if the mean density of the two
luminaries be equal, the velocities of bodies able to escape
into space from the spheres of attraction will stand in the
ration of the cube roots of their masses, and therefore a
luminary from whose surface particles endowed with a velocity of
300,00,000 meters/second could escape must have a mass
120,000,000 times that of the sun, for only particles having a
velocity of 608,000 meters/second can escape from the sun, and
this stands to 300,000,000 in the ratio of 1:493, and the cube
of 493 is nearly 120,000,000.

But, so far we have no reason for admitting the existence of
such a huge body, and therefore it seems to me that the velocity
of the particles of our gas (ether) must, in order to permeate
space, be greater than 2,240,000 meters/second and probably less
that 300,000,000 meters /second.

Hence the atomic weight of *x* as the lightest elementary
gas, permeating space and performing the part of the ether, must
be within the limits (formula II) of 0.000,000,96 and
0.000,000,000,053, if that of H = 1.

I think it is impossible, under the present conditions of our
scientific knowledge, to admit the latter value, because it
would in some measure answer to a revival of the emission theory
of light, and I consider that the majority of phenomena are
sufficiently explained by the fact that *the particles and
atoms of the lightest element x capable of moving freely
everywhere throughout the universe have an atomic weight
nearly one millionth that of hydrogen, and travel with a
velocity of about 2,250 kilometers/second.*

When I was making these calculations, my friend Professor Dewar
sent me his presidential address to the Belfast meeting of the
British Association. In it he expresses the thought that the
highest regions of the atmosphere, which are the seat of the
aurora borealis, must be considered to be the province of
hydrogen and of the argon analogs. This is only a few steps from
the yet more distant regions of space and from the necessity of
recognizing the existence of a still lighter gas capable of
permeating and filling space and thus giving a tangible reality
to the conception of the ether.

In conceiving the ether as a gas endowed with the above
properties, and belonging to the zero group of elements, I
desired before all to extract from the periodic law that which
it was able to give and to tangibly explain the materiality and
universal presence of an ethereal substance throughout nature,
and also to explain its faculty of permeating all substances,
gaseous, liquid and solid. The atoms of even the lighter
elements forming the ordinary substances being several million
times heavier than those of ether, they are not likely to be
greatly influenced in their mutual relations by its presence.

Of course there are still many problems to be solved, but I
think the majority are unfathomable, and I have no intention of
raising them here or of trying to solve those which appear
capable of being solved. My only purpose has been to state my
opinion on a subject about which I know many are thinking and
some are beginning to speak.

Without going into a further development of our subject, I
should like to acquaint the reader with some, at first sight,
auxiliary circumstances which guided my thoughts and led me to
publish my opinions. These consist of a series of recently
discovered physico-chemical phenomena which are not subject to
the ordinary doctrines of science, and have cause many to return
to the emission theory of light, or to accept the, to me, vague
hypothesis of electrons, without trying to explain to the utmost
the familiar concept of an ethereal medium transmitting luminous
vibrations, &c. This more especially refers to radioactive
phenomena.

I need not describe there most remarkable phenomena, assuming
that the reader is more or less acquainted with them; and will
only mention that a perusal of the literature of the subject,
and what I saw in M. Becquerels laboratory and heard from him
and Monsieur and Madame Curie, gave me the impression of some
peculiar state proper chiefly (but not exclusively, just as
magnetism is chiefly, but not exclusively, the property of iron
and cobalt) to uranium and the thorium compounds.

As uranium and thorium, and also radium, judging from Madame
Curies researches (1902), have the highest atomic weights
(U=239, Th = 232, and Rd = 224) among the elements, they may be
looked upon as suns, endowed with the highest degree of that
individualized attractive capacity, a mean between gravity and
chemical affinity, which is seen in the absorption of gases,
solution, &c. By conceiving the substance of the ether as
the lightest of gases, *x*, deprived, like helium and
argon, of the power to form stable definite compounds, it need
not be imagined that this gas is deprived of the faculty of, as
it were, dissolving in or accumulating about large centers of
attraction like the sun among heavenly bodies, or uranium and
thorium in the world of atoms. As a matter of fact, direct
experiment proves that helium and argon are able to dissolve in
liquids, and, moreover, to individualize this faculty according
to either their own nature or that of the liquid and according
to the temperature. If the ether is a gas, *x*, it must
naturally accumulate from all parts of the universe towards the
medium or mass of the sun, just as the gases of the atmosphere
accumulate in a drop of water. And the lightest of gases, *x*,
will also accumulate about the heaviest atoms of uranium and
thorium, and perhaps change its form of motion like a gas
dissolved in a liquid. This will not be a definite act of
combination, determined by a conformable harmonious motion, like
the motion of a planet and its satellites, but an embryo of such
a motion, resembling that of a comet in the region of heavenly
individualizations, and it may be looked for sooner in the
region of the heaviest atoms of uranium and thorium than in
those of the lighter elements, just as a comet falling from
space into the planetary system revolves round the sun and then
once more escapes into space. If such a special accumulation of
ether atoms about the molecules of uranium and thorium be
admissible, they might be expected to exhibit peculiar
phenomena, determined by the emission of a portion of this ether
held by particles of normal mean velocity and by new ether
entering into the sphere of attraction. It seems to me that the
optical and photo-radiant phenomena, not to mention the loss of
electrical charges, indicate a material flow of something which
has not been weighed, and it appears to me that they might be
understood in this manner, for peculiar forms of the entrance
and egress of ether atoms should be accompanied by such
disturbances in the ethereal medium as give the phenomena of
light. Monsieur and Madame Curie showed me the following
experiment, for instance. Two small flasks were connected
together by a lateral tube fused into their necks, and having a
stopcock in the middle. The cock being closed, a solution of the
radioactive substance was poured into one of the flasks, while
the gelatinous white precipitate of sulfide of zinc, shaken up
in water, was placed in the other flask. Then both flasks were
closed. So long as the cock between the flasks remained closed,
nothing is visible in the dark; but directly as it is opened,
the sulfide of zinc becomes brilliantly fluorescent and
continues so as long as the tube connecting the flasks remains
open. This experiment gives the impression of an emissive flow
of something material from the radioactive substance, and, in a
sense, seems comprehensible if we assume that a peculiar refined
ether gas, capable of exciting luminous vibrations, enters and
passes off from the radioactive substance. Just as any kind of
motion may be set up in a gas, not only by a solid piston, but
also by the motion of another portion of the same gas, so also
the phenomenon of light, i.e., a certain transverse vibration of
the ether, may be produced not only by the molecular motion of
particles of other bodies (by heating them or otherwise)
bringing the ether from its state of mobile equilibrium, but
also by a certain change in the motion of the ether atoms
themselves; i.e., by their destroying their own equilibrium
which may be caused in the case of radioactive bodies by the
massiveness of the atoms of uranium and thorium, just as the
luminosity of the sun may be, I think, due to its great mass
being able to accumulate ether in far larger quantities than the
planets, &c. I think that the radio-luminous phenomena,
i.e., such as proceed at right angles to the ray of the
vibration of the ether medium, consisting of minute atoms in
rapid motion, are, as a matter of fact, more complex than has
hitherto been thought, chiefly owing to the fact that the
velocity of the ether atoms is not very much less (180 times)
than that f the propagation of their transverse vibrations. This
at all events was the impression I acquired from the radioactive
phenomena I saw, and I do not conceal it, although I consider it
very difficult to form any opinion on this still dim province of
the phenomena of light.

In conclusion, I may mention another class of phenomena, which
led me to this conception of the ether. Dewar, about 1894, in
his researches on the phenomena proceeding at low temperatures,
observed that the phosphorescence of many substances, and
especially of paraffin, becomes more intense at the temperature
of liquid air (between -181 deg and -193 deg). Now, it appears to me
that this is due to the fact that paraffin and such like
substances have a great capacity for condensing the atoms of
ether at very low temperatures. In other words, that the
solubility (absorption) of the ether atoms in some bodies
increases in extreme cold. They therefore become more
phosphorescent, for the vibrations of light are then set up in
the phosphorescent substances, not only by their own atoms
(having the property of illumination at their surface, of
passing into a state of peculiar tension, which causes, when the
act of illumination ceases, the ether to vibrate), but also by
the atoms of ether which condense in these bodies and set up a
rapid state of interchange with the surrounding medium.

It seems to me that this conception of ether, as a peculiar
all-permeating gas, gives a means, if not of analyzing such
phenomena, at all events of understanding their possibility. I
do not regard my imperfect endeavor to explain the nature of
ether from a chemical point of view as more than the expression
of a series of thoughts which have arisen in my mind, and which
I have given vent to solely from a desire that these thoughts,
being suggested by facts, should not be utterly lost. Most
probably similar thoughts have come to many, but unless they are
enunciated they often pass away without being further developed.
If they contain a particle of that natural truth which we all
seek, my effort will not have been in vain; it may then be
worked out, embodied and corrected, and if my conception be
proved false in its basis, it will prevent others from repeating
it. I know of no other way for slow and steady progress. And
even if it be found impossible to recognize in the ether the
properties of the lightest, most mobile, and chemically inactive
gas, still, if we keep to the realm of science, we cannot deny
its substantiality, and this requires a search for its chemical
nature. My effort is no more than a tentative answer to this
primary question, and its one objective is to bring this
question to the fore.

October 1902

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