Richard Chapin: Interstellar Light Collector --- Article
& patent

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**Richard CHAPIN**

**Interstellar Light Collector**

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**<http://features.us.reuters.com/techlife/news/N04633430.html>**

Tim Gaynor  , Reuters 9 Dec 2007

**Interstellar Light Collector**

**Jeff Topping**

 Light from a full moon is reflected off
the 'Interstellar Light Collector' (R) onto people in a
moveable trailer (small lighted object in center of photo) in
the Sonoran desert near Three   
 Points, Nov. 23, 2007.

 Financial advisor Jaron Ness stands in the
cool desert air waiting for the clouds to clear and the moon
to rise.

 As the conditions come into alignment, he
steps into the path of a cool blaze of blue-white light
bounced off a wall of highly polished parabolic mirrors five
stories high.

 "It feels magnetic," he says, turning his
hands slowly in the reflected glow of the light from the
almost full moon.

 The young professional from Colorado is
among a growing number of curious people beating a path to
this patch of scrub-strewn land out in the Arizona desert to
bask in light from the   
 world's first moonbeam collector.

 A Tucson-based inventor and businessman
Richard Chapin and his wife Monica are behind the giant
device, which gathers up and focuses the light of the moon.

 The effect of the moon's gravitational
pull on the Earth's tides and other natural phenomena has been
studied for millennia. Less attention has focused on the
sunlight reflected from its surface.

 The Chapins built the large, one-of-a-kind
contraption that stands in the desert some 15 miles west of
Tucson, Arizona, in the belief that moonlight might have
applications for medicine,   
 industry and agriculture.

 "So much work has focused on the sun. We
have just forgotten about this great object that has been here
for billions of years, has affected us in all forms of our
evolution," said Chapin, who   
 paid for the project with his own money.

 "If it could affect plants and animals ...
I thought, 'what could the amplification of that light do?"'

**BATHING IN MOONLIGHT**

 Neither of the Chapins are scientists. The
couple used income from a popular swap meet they own in Tucson
to develop what they call their "Interstellar Light
Collector," which has so far   
 cost them $2 million.

 It consists of a large frame sunk into a
45-foot-deep crater, on private land in sparse desert, in an
area known for its dark skies a few miles from the Kitt Peak
National Observatory.

 The device is five stories tall and weighs
25 tons, and is covered with 84 mirrored panels set on a
hydraulic mount that, the Chapins say, can focus the light of
the moon with "the precision   
 of a Swiss watch."

 There is no charge to use the facility,
although the couple accept donations of $10 from people who
use it to defray some of the operating costs.

 So far they have had more than 1,000
visitors, with interest from as far a field as Australia,
Japan, India and Saudi Arabia from people seeking either a new
experience or in the hope of   
 some kind of medical benefit.

 Some dress in robes, others strip to their
underwear to bask in the moon glow from the glittering bank of
mirrors, spending anywhere from three minutes to 15 minutes at
a time.

 Visitors enjoy the experience. Some say it
is like swimming underwater, while others say it feels like
standing in a warm breeze and leaves them feeling upbeat.

 "When I got in the moonlight it was an
instant and profound sense of euphoria ... it was very
peaceful," said Eric Carr, a hypnotherapist from Tucson who
has visited several times.

**BENEFITS OF LIGHT**

 Some visitors to the site believe that
exposure to the moonlight has helped alleviate some medical
conditions. After bathing in the moonbeams, Carr said he
noticed an improvement in a   
 long-standing asthma condition.

 However, no clinical experiments with
moonlight have been carried out on people. Scientists say
there is no proof that it has any effect whatsoever on medical
conditions and diseases, and   
 are skeptical of anecdotal claims.

 "I haven't seen any hard scientific
evidence that it's not a placebo effect. There hasn't been
enough real research on it yet to say that it's doing
anything," said Katherine Creath, research   
 professor of optical sciences and medicine at the
University of Arizona.

 "But whether or not it's the placebo
effect or the light, I don't think that matters as long as
people feel like they are having a positive effect, then it's
worth it to them to do it," she added.

 The Chapins are eager for researchers to
use the site to determine if moonlight does have any
demonstrable applications in areas including medicine, plant
biology and certain industrial   
 processes. They also welcome visits by skeptics to the
site.

 Meanwhile, visitors continue to trek out
to the imposing installation and listen to ambient music as
they wait for a break in the clouds to step into the
moonlight. For them, it is a very   
 enjoyable experience in itself.

 "You feel almost like you are in heaven,"
said Aranka Toniatti, a cancer patient who has driven from
Colorado twice to stand in the moonlight. "It's a gorgeous
feeling."

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**Interstellar Light Collector**

**USP Appln. # 2007008616**

( 2007-01-11 )

CHAPIN, Richard   
Classification: - international: G02B23/00; G02B23/00; -
European: G02B19/00; A01G7/04   
Application number: US20050174948 20050705   
Priority number(s): US20050174948 20050705   
Also published as: WO2007005352 (A3); WO2007005352 (A2)

**Abstract ---** Devices and methods that
collect, concentrate, and disperse celestial light into
spectra of different wavelengths by utilizing a large
collection mirror and a means for dispersion located at a
focal point.

Correspondence Name and Address:   
QUARLES & BRADY STREICH LANG, LLP   
ONE SOUTH CHURCH AVENUE, SUITE 1700   
TUCSON, AZ 85701-1621

U.S. Current Class:  359/399; 359/407   
U.S. Class at Publication:  359/399; 359/407   
Intern'l Class:  G02B 23/00 20060101 G02B023/00

**Description**

**BACKGROUND OF THE INVENTION**

**[0001] 1. Field of the Invention**

[0002] The invention is directed generally to
devices and methods for collecting and concentrating light
emanating from outer space and celestial bodies, including,
but not limited to, stars, planets, moons, and comets. More
specifically, the invention involves interstellar light
collection apparatus and methods for collection, selection of
component wavelengths (e.g., through dispersion), and
application of interstellar light to matter for investigative
purposes.

**[0003] 2. Background of the Invention**

[0004] Since the dawn of time, "light" (i.e.,
the electromagnetic spectrum) has been instrumental in
everything from photosynthesis to modern photography. Solar
light has been harnessed in photovoltaic cells to create
electricity, light has been manufactured artificially to
promote plant growth, and even non-visible light has been used
in various medical applications such as X-rays and tumor
detection devices.

[0005] Indeed, a large quantity of background
reading is available on the subject of the industrial and
medical application of light (see, for example, National
Research Council, Harnessing Light. Optical Science and
Engineering for the 21.sup.st Century, National Academy Press,
1998; Kaler, James B., Stars and Their Spectra: An
Introduction to the Spectral Sequence, Cambridge University
Press, 1989; Scranton, Bowman, & Peiffer, Editors,
Photopolymerization: Fundamentals and Applications, American
Chemical Society, 1996; and Kalyanasundaram & Gratzel,
Photosensitization and Photocatalysis Using Inorganic and
Organometallic Compounds, Kluwer Academic Publishers, 1993).

[0006] Current technologies for collecting
celestial light involve the use of "light buckets," i.e.,
optical receiving telescopes that collect photons but are not
diffraction limited. In other words, a light bucket cannot
concentrate photons into a very small tightly focused spot.

[0007] Accordingly, light bucket technologies
are hampered by the inability to concentrate light as would be
useful in various methods of application, such as lasers.
Moreover, traditional telescopes do not provide a means for
dispersing focused light into component spectra for industrial
or medical experimentation and application.

[0008] Thus, there exists a need for methods and
devices for improved collecting, concentrating, and dispersing
celestial light.

**SUMMARY OF THE INVENTION**

[0009] The invention relates in general to
devices and methods for celestial light collection,
concentration, and application. More specifically, the
invention includes devices and methods for collecting,
concentrating, and separating celestial light of different
wavelengths and frequencies by utilizing a collection mirror
and a means for dispersion located at a focal point.

[0010] It is the intended use of the inventive
device to collect and harness interstellar light in order to
utilize the uniqueness of its spectra for the benefit of
humankind through various applications. Hence, the invention
will collect, harness and apply the spectrums and intensities
of the stars and other celestial bodies, which are notably
different from the spectrum of the sun, and furthermore cannot
be duplicated anywhere on earth.

[0011] This invention builds upon the principles
and technology of basic telescopes. Instead of merely looking
upon celestial bodies from earth, the present invention
collects and concentrates light from celestial bodies down
from the heavens and separates that light into various
spectrums.

[0012] In one embodiment, the inventive method
includes the steps of collecting light from a celestial source
by utilizing a mirror, focusing the light collected by the
mirror to a focal point, dispersing the focused light
utilizing an aperture located at the focal point, and exposing
terrestrial matter to at least a portion of the dispersed
light.

[0013] Thus, it is a primary objective of the
invention to provide a celestial light collector for
concentrating and selecting light from celestial sources.

[0014] Another embodiment of the invention
relates to a celestial light collector that includes a mirror,
a focus cage disposed along a focal axis of the mirror, and a
means for dispersing celestial light reflected by the mirror,
wherein the means for dispersing is located along the focal
axis and housed within the focus cage.

[0015] In another embodiment of the invention, a
fresnel lens adapted to refract celestial light within a focus
cage is utilized as, or in addition to, the means for
dispersing. Alternatively, the means for dispersing light
includes a lens between 0.5 and 8 millimeters in thickness or
a prism.

[0016] Preferably, the mirror of the embodiments
above is a polycarbonate parabolic mirror that is between 0.5
and 1.0 millimeters in thickness. Also preferably, the mirror
is an altitude-azimuth off-axis segmented mirror that is
between 2,000 and 4,000 square feet in size.

[0017] An aspect of the invention is that
celestial light travels unobstructed into the focus cage,
which may be disposed upon a rotating base member to better
align with the mirror/collector. Moreover, the mirror itself
in an embodiment of the invention is made rotatable by being
disposed upon a rotating base member. Preferably, the rotating
base member is a vertical axis azimuth stewing ring disposed
atop a concrete pad.

[0018] Given the wind shear and other potential
constraints on utilizing large exposed mirrors (i.e., mirrors
not housed within a structure such as a building or silo), the
mirror preferably is disposed within a topographic depression,
the depth of which is equal to at least one-third of the
height of the mirror.

[0019] Another embodiment of the invention
features a celestial light collector that includes a parabolic
mirror supported by a structure including struts and at least
a pair of slewing rings such that the structure is rotatable
in a horizontal plane, a focus cage disposed along a focal
axis of the mirror, and a means for dispersing celestial light
reflected by the parabolic mirror, with the means for
dispersing located along the focal axis and housed within the
focus cage.

[0020] In accordance with these and other
objects there is provided new and improved devices and methods
for collecting, concentrating, and selecting celestial light
spanning light spectra of electromagnetic radiation (e.g.,
infrared, visible, and ultraviolet light).

[0021] Various other purposes and advantages of
the invention will become clear from its description in the
specification that follows. Therefore, to the accomplishment
of the objectives described above, this invention includes the
features hereinafter fully described in the detailed
description of the preferred embodiments, and particularly
pointed out in the claims. However, such description discloses
only some of the various ways in which the invention may be
practiced.

**BRIEF DESCRIPTION OF THE DRAWINGS**

[0022] **FIG. 1** is a schematic side
elevational view of an apparatus of the invention.

[0023] **FIG. 2** is a schematic side
elevational view of a second embodiment of the invention.

[0024] **FIG. 3** is a front elevational
view of a third embodiment of the invention.

[0025] **FIG. 4** is a cross-sectional
detail view along line 4-4 from FIG. 3 showing the layer
composition of a preferred mirror segment.

[0026] **FIG. 5** is a block diagram
illustrating method steps of the invention.

**DESCRIPTION OF EXEMPLARY EMBODIMENTS**

[0027] The invention relates in general to
devices and methods for collecting, concentrating, and
separating celestial light of different wavelengths and
frequencies by utilizing a relatively large collection mirror
and a means for dispersion located at a focal point. As such,
the invention does not provide images of celestial objects.

[0028] The section headings used herein are for
organizational purposes only and are not to be construed as
limiting the subject matter described. All references cited in
this application are expressly incorporated by reference for
any purpose.

[0029] The term "celestial light" refers to
light or electromagnetic spectra originating from somewhere
other than the earth and covering the entire range from
ultraviolet to infrared.

**I. Celestial Light Collectors**

[0030] FIG. 1 is a side elevational view of a
first embodiment of the invention. Shown is a celestial light
collector 2 that includes a mirror 3, preferably of parabolic
configuration and manufactured of polycarbonate between 0.5
and 1.0 millimeter in thickness, supported by a substrate 5
and made rotatable by pivot 6. The pivot 6 is disposed
horizontally on a stand 8, which is joined to a rotatable base
10 in a pad 11 of, preferably, cement. The pivot 6 and base 10
allow the mirror 3 to be adjusted in both the vertical and
horizontal planes.

[0031] A focus cage 12 is disposed along a focal
axis A of mirror 3 and positioned a distance from the mirror
corresponding to a focal point f.sub.p. Located along the
focal axis A and housed within the focus cage 12 is a means 14
for dispersing celestial light reflected by the mirror 3.
Preferably, the means 4 for dispersing light is located at the
focal point f.sub.p, thereby concentrating the spectrum before
dispersion takes place. Exemplary means for dispersing light
include, but are not limited to apertures, such as filters,
lenses, diffraction gratings, and prisms.

[0032] Although not shown in this figure, the
collector 2 may further include a fresnel lens and/or a
parabolic mirror adapted to refract celestial light within the
focus cage.

[0033] In order to collect and concentrate a
large amount of light, the collector 2 must be relatively
large. Preferably, the mirror 3 is actually a segmented array
made up of many smaller mirror areas that total between 2,000
and 4,000 square feet. Given this large size, the focus cage
12 and mirror 3 preferably are not co-located within a common
building. Indeed, for the collector illustrated by FIG. 1,
there is 100 feet of open distance between the mirror and the
focus cage. Accordingly, the distance between the focus cage
and mirror such that the cage can be located at a focal point
will necessarily depend on the mirror size.

[0034] In this regard, the focus cage 12
preferably is mobile. Mobility may take the form of rotation,
such as that achieved by having the focus cage 12 disposed
upon rotating base member 16, or, for example, by attaching
the cage to a track system (not illustrated) such that it may
move toward or away from the mirror 3 or concentrically around
the mirror as the mirror rotates.

[0035] Unlike spectroscopes, the collector of
the invention does not rely on slits or diffraction gratings
to separate light into component wavelengths, and the
celestial light collected by the mirror does not pass through
analytical instrumentation, such as a photomultiplier or
photodetector. Moreover, in contrast to spectroscopes, the
invention concentrates interstellar light before dispersion
into component wavelengths takes place.

[0036] To reduce stress such as wind shear upon
the invention, the collector 2 preferably is disposed within a
topographic depression, the depth of which is equal to at
least one-third of the height of said mirror. However, in the
embodiment illustrated in FIG. 1, the collector 2 is disposed
in a depression that is approximately sixty feet deep from
ground level, which well exceeds one-third of the mirror
height (also about sixty feet).

[0037] Turning to FIG. 2, a light collector
array 20 of the invention is shown. The collector array 20
includes a parabolic mirror 22 housed within a structure of
struts 24, with a pair of slewing rings 26 disposed at each
end of the parabolic mirror 22. The slewing rings 26 provide
for attitude control, and, moreover, allow light reflected
from the mirror to travel unobstructed to the focus cage 30
along an optical axis B. The focus cage 30 is a building that
will preferably contain research subjects, organic and
inorganic matter, etc., onto which light may be applied.

[0038] Preferably, the structure of struts 24 is
mounted upon a rotatable base 32, such as a vertical axis
azimuth stewing ring 34 bolted atop a concrete pad 36. Also
preferably, the focus cage 30 is disposed along focal axis B
of the mirror 22 such that a means 38 for dispersing celestial
light reflected by parabolic mirror 22 is located at a focal
point (f.sub.p2) that is housed within the focus cage.

[0039] As a result of locating the dispersion
means 38 at focal point f.sub.p2, concentrated light is
separated into component wavelengths (e.g., .lamda..sub.1,
.lamda..sub.2, .lamda..sub.3). One or more of the component
wavelengths are then used to expose matter (in this case
biological matter 40), thereby ascertaining the effects of a
spectrum of light not found on the earth. The concentrated
light may further be manipulated by, for example, fresnel lens
41 or prism 42 before matter exposure.

[0040] Preferably, the collector 20 has only a
single mirror to reflect light to the focus cage 30, allowing
light to travel unobstructed thereto. Also preferably, the
means for dispersing light includes a lens between 0.5 and 8
millimeters in thickness.

[0041] Turning to FIG. 3, a third embodiment of
a mirror of the invention is shown.

[0042] Mirror 44 is composed of an array of
segments 46 and is preferably parabolic in shape. The segments
46 are surrounded by a drive ring 48 that is in rotational
contact with altitude yoke 50 via rollers 52. The altitude
yoke 50 preferably surrounds the drive ring 48, although only
a cut-away portion is shown in this particular illustration.

[0043] The segmented design allows the
construction of relatively large mirrors, i.e., 20-80 feet in
diameter. Given this relatively large mirror size, the
concentration of interstellar light is believed to be well
beyond known collectors, in that the concentrated light is at
least five orders of magnitude brighter than a single object
viewed.

[0044] FIG. 4 is a cross-sectional view of an
individual mirror segment. A thin (e.g., 0.5 millimeter)
plastic mirror 56 (e.g., polycarbonate) is laminated onto a
foam substrate 58. The foam substrate may include, for
example, a five centimeter slab of urethane. The foam
substrate layer 58 is further laminated onto a rigid panel 60,
such as aluminum sandwiched between fiberglass for good
thermal conductivity.

**II. Methods for Concentrating and Selecting
Celestial Light by Wavelength and/or Frequency**

[0045] As summarized in FIG. 5, the inventive
method for collecting celestial light includes the steps of
collecting light from a celestial source by utilizing a
mirror, focusing the light collected by the mirror to a focal
point, dispersing the focused light utilizing an aperture
located at the focal point, and exposing terrestrial matter to
at least a portion of the dispersed light.

[0046] In some applications, the method of the
invention may further involve collimating the collected and/or
dispersed light, utilizing a fresnel lens, or utilizing a
polycarbonate parabolic mirror prior to dispersion.
Preferably, the mirror comprises a polycarbonate mirror
structure that is between 0.5 and 1.0 millimeters in thickness
and is disposed upon a mobile supporting structure. Moreover,
the focal point aperture preferably is a lens between 0.5 and
8.0 millimeters in thickness.

[0047] In other applications, the concentrated
interstellar light is collimated and further pinpointed to
less than a millimeter by using fresnel lenses or parabolic
mirrors. In still other applications, the collimated light is
pulsed or strobed. Due to the barriers, such as the
atmosphere, and the relatively weak intensity of
un-concentrated interstellar light, the method presents a
unique opportunity to expose biological matter to previously
unknown spectra.

**III. Applications of Collected and
Concentrated Celestial Light**

[0048] In certain embodiments, methods for
applying concentrated and selected celestial light are
contemplated.

[0049] 1) Medical: [0050] A) Photo Dynamic
Therapy--Using light to treat cancer, detect tumors, and to
treat skin diseases such as psoriasis. Other uses would be to
treat ailments such as Seasonal Affective Disorder or clinical
depression. [0051] B) Surgery--Using light to develop new
technologies for minimally invasive therapies, methods that
reduce trauma involved with traditional surgical techniques.
[0052] C) Optical Diagnostic Techniques--In this field, light
has such applications as blood monitoring, retinal
photography, and glucose monitoring in diabetes.

[0053] 2) Entertainment: [0054] A) LASER Light
Shows--Entertaining light shows, often choreographed with
music, such as those seen at hotels and casinos in Las Vegas,
Nev., or at amusement parks. [0055] B) Holograms--Including
advancements in reversible holography and switched holographic
gratings.

[0056] 3) Agriculture [0057] A) Germination:
Using light to stimulate or inhibit the growth processes, such
as photoblastic stimulus of seeds. One potential use would be
longer seed dormancy. [0058] B) Phytochromatic Stimulus: Using
light to control responses of the photoreceptor phytochrome in
plants, in order to stimulate desired growth patterns. [0059]
C) Vegetative Stimulus: Using light to stimulate the major
growth receptors in plants, such as cytokinine, in order to
achieve desired effects.

[0060] 4) Industry: [0061] A)
Photopolymerization: Currently, there are a myriad uses for
photopolymerization. Four such applications would involve
using light to create the following: plastics that are more
durable, adhesives, sealants, and metal coatings. [0062] B)
Photolithography: Using light essentially as an enabler in
integrated circuit processing. [0063] C) Optical storage:
Using light to enable existing technologies, such as compact
disks, to store more information. [0064] D) Printing
Materials: Including pre-press proofing systems, printing
inks, printing plates, and the production of Braille
materials.

[0065] 5) Scientific Research: [0066] A)
Photochemistry: Including experimentation through
photosensitization and photocatalysis. [0067] B) Photoelectric
Effect

[0068] The invention, having been described
above, may be better understood by reference to examples. The
following examples are intended for illustration purposes
only, and should not be construed as limiting the scope of the
invention in any way.

**PROPHETIC EXAMPLES**

**Example 1**

[0069] Celestial light is concentrated and
selected for application to the skin of a test subject
suffering from depression. This can be achieved with as little
as 30 min. of very bright light near 10,000 lux or with a
couple hours of light of about 2500 lux so as to simulate an
average daily exposure for light, i.e., 250 or more lux for a
sunny location.

**Example 2**

[0070] A theory has been developed that
celestial pure light, being comprised of alpha particles,
ions, protons and neutrons, is different than artificially
produced light; and, that this light comes in various
wavelengths and frequencies and therefore various colors. The
invention could be used to test this theory by collecting,
concentrating, and dispersing celestial light so that its
color, wavelength, and frequency can be studied and compared
with artificially produced light.

**Example 3**

[0071] A theory has been developed that the
effects of the celestial pure light on the growth of various
polymers and crystals will result in important shapes, sizes
and structures in the industrial and scientific communities.
This theory would be tested by exposing polymers and crystals
to different wavelengths and intensities of celestial light
collected, concentrated, and dispersed according to the method
of the invention.

**Example 4**

[0072] A theory has been developed that
celestial light will have profound effect on the chromophores
in plants, and also the phytochromes, yielding various growth
factors. To test this hypothesis, plant matter will be exposed
to different wavelengths and intensities of celestial light
collected, concentrated, and dispersed according to the method
of the invention.

**Example 5**

[0073] A theory has been developed that
utilizing the various wavelengths and frequencies of the
celestial bodies will show results that are different than
what is being researched in reference to porphyrins. In
particular, we propose to expose porphyrins to different
wavelengths and frequencies of celestial light collected,
concentrated, and dispersed according to the method of the
invention.

[0074] Various changes in the details and
components that have been described may be made by those
skilled in the art within the principles and scope of the
invention herein described in the specification and defined in
the appended claims. For example, the mirror of FIG. 3 may
instead be trapezoidal in configuration. Therefore, while the
present invention has been shown and described herein in what
is believed to be the most practical and preferred
embodiments, it is recognized that departures can be made
therefrom within the scope of the invention, which is not to
be limited to the details disclosed herein but is to be
accorded the full scope of the claims so as to embrace any and
all equivalent processes and products.

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