THOTH 
A Catastrophics Newsletter 

VOL VI, No 5 
Aug 30, 2002 

EDITOR: Amy Acheson 
PUBLISHER: Michael Armstrong 
LIST MANAGER: Brian Stewart 

CONTENTS 
BACK TO BASICS . . . . . . . . . . . . . . . . . . . . Mel Acheson 
MICROBES IN GEOLOGY: part 1 . . . . . . . . . . . . . Earl Staelin 
WATER ON MARS? . . . . . . . . . . . . . . . . . . . Wal Thornhill 
>>>>>>>>>>>>>>>>>>>-----<<<<<<<<<<<<<<<<<<< 

BACK TO BASICS 
By Mel Acheson 

Newton, Einstein, Darwin and the other early explorers of science 
discovered the "New World" of fundamental laws of reality, and the 
scientists who have come after them are mere colonists. 
Continuing this line of thought, John Horgan writes in THE END OF 
SCIENCE that the latecomers have only two choices: to apply those 
fundamental discoveries in the construction of derivative theories 
or "to pursue science in a speculative, post-empirical mode that I 
call ironic science.... [Ironic science] offers points of view, 
opinions, which are, at best, interesting, which provoke further 
comment. But it doesn't converge on the truth. It cannot achieve 
empirically verifiable surprises that force scientists to make 
substantial revisions in their basic description of reality." 
Horgan classifies most modern theories as ironic science: 
superstring theory and the inflationary big bang and punctuated 
equilibrium. 

This interesting opinion provokes me to make a couple of further 
comments. A "basic description of reality" is not the same thing 
as "fundamental laws". Fundamental laws are generalities. 
Reality is concrete. A description of reality asserts, among 
other things, which fundamental law applies in which real 
situation. Between the laws and reality lies the description, in 
which scientists select which laws to apply. 

The accepted description of reality in astronomy asserts that only 
the law of gravity applies in space. The law can be Newton's or 
it can be Einstein's, but it cannot be Darwin's law of evolution. 
A description of astronomical reality based on Darwin's law 
probably wouldn't make any sense, but the point is that one law is 
selected and another is not. Even the particle physicists who 
lately have invaded astronomy select only certain fundamental laws 
on which to construct their basic description of atomic reality. 

This business of selection is so simple as to be not worth 
mentioning. But not mentioning it leads to not paying attention 
to it, which leads to skipping over it in the occasional 
circumstance when it may be important. My next comment, of 
course, is that it's important now. 

Horgan and the scientists he interviewed for his book have 
overlooked a deeper irony. While the theories of ironic science 
have been unable to "achieve empirically verifiable surprises", 
experimental and observational science has produced a flood of 
them. Nearly every discovery of the space age, from the Van Allen 
radiation belts around the Earth to the high velocity winds around 
Neptune, has been announced as a surprise. And the surprises have 
been surprising precisely because they haven't verified the 
prevailing "basic description of reality." 

One might think a reasonable plan in this circumstance would be to 
take a second look at the fundamental laws selected for one's 
description. One doesn't have to resort to anything as ridiculous 
as considering Darwin's law: For instance, the laws of 
electromagnetism have been lying around for over a century, mostly 
ignored (because "you can't get charge separation in space") 
except by a few electrical engineers. 

The problem is that scientists are like the horse led to water: 
Neither the failure of ironic science to achieve empirical 
surprises nor the failure of achieved empirical surprises to 
verify the accepted description can force scientists to drink 
basic revisions if they don't want to. 

Selection is the result of wanting to choose, and if you want to 
defend a theory you can always find expedient excuses. Almost 
nothing outside the solar system and a lot of things inside it 
don't obey either Einstein's or Newton's law of gravity: E.g., the 
stars in the arms of spiral galaxies revolve at about the same 
velocity instead of slowing down with distance as gravity 
predicts. To make these observations fit the gravitational 
description of reality, astronomers have chosen to hedge the 
fundamental law with a thicket of ironic "opinions" and "points of 
view" that are not empirical: There might be appropriately 
configured halos of unseen "dark" matter outside the galaxies that 
produce the observed velocities. This avoids the necessity of 
questioning fundamentals. But it turns the basic description of 
reality into an imaginative fantasy that is explanatory but 
neither verifiable nor falsifiable. Modern theories, with 
appropriate adjustments, can explain everything and anything, just 
as psychoanalysis, with childhood trauma, the dark matter of the 
mind, can explain any behavior. 

However, the point of science is not merely to explain but to find 
out which explanation is actually the case. For that, you need 
more than one explanation from which to choose. This object might 
be a black hole; that object might be dark matter. Having 
disallowed competition from fundamentally different theories, 
there's no way to tell if those objects might be something else. 
Verification alone is inadequate: You need to search for 
alternatives and to test them to gain reliability. (See "The 
Epistemology of Error" by Douglas Allchin.) 

Planting more hedges of ad hoc hypotheses around the fundamental 
law of gravity may appeal to ironic scientists. But other 
scientists, mostly outside astronomy, are more inclined toward 
empirical results. The new field of plasma cosmology has admitted 
Maxwell's laws of electromagnetism to the description of 
astronomical reality. The properties of electrical discharges 
applied to the phenomena of space by such pioneers as Birkeland, 
Langmuir, and Alfven explain the new discoveries without ironic 
fantasies. The revised description expects the observations that 
are surprising to the standard gravity-only version. And this 
electrical description is directly verifiable in plasma labs. 
Dark matter and ten-dimensional superstrings are not. 

The reality we think we see is constantly being revised by what we 
actually see of a partially known reality. (See, e.g., "The 
Sensory Order" by F.A. Hayek.) Usually the revisions are 
superficial. But there have been times in the history of thought 
when the revisions have reached to the basics. Plasma cosmology 
hasn't discovered a new fundamental law. It merely replaces one 
law (gravity) with another (electromagnetism). But the effect on 
the basic description of astronomical reality is as great as if a 
new law had been discovered: We think we see an entirely new 
reality. 

This shouldn't be a surprise. The space age has brought 
substantial revisions in instrumentation, allowing us to sense the 
entire electromagnetic spectrum from radio wavelengths to gamma 
wavelengths. For the first time in human history, we are not 
restricted to an anthropocentric sensory viewpoint. The space age 
has also brought substantial revisions in location, allowing us to 
sense the cosmos from positions off the Earth's surface. For the 
first time in human history, we are not restricted to a geocentric 
positional viewpoint. 

We should expect these revisions in basic viewpoint to be 
accompanied by a revision in the basic description of the reality 
viewed. The ultimate irony would be that, in the face of our 
liberation from an anthropocentric and geocentric viewpoint, we 
would be unable or unwilling to liberate ourselves from a 
traditional way of thinking about reality. 

Mel Acheson 
thoth at whidbey.com 

************************************************************ 

MICROBES IN GEOLOGY 
By Earl Staelin 

THE AMAZING ROLE OF MICROBES IN GEOLOGY: 
ARE BIOLOGICAL TRANSMUTATIONS INVOLVED?
Copyright, July, 2002 

EXCERPTS:
The past twenty years has witnessed a revolution in geology-the 
discovery that microorganisms or microbes play a major role in 
many geological processes in the crust of the earth. The evidence 
goes back over 200 years ... [forcing] Geologists to take a new 
look at old problems in which microbes appear to play a prominent 
part. [Among these are] the formation of limestone, petrified 
wood and bone; the formation of elements such as hydrogen, carbon, 
oxygen, magnesium, calcium, silica, aluminum, phosphorus, 
chlorine, and sulphur; the formation of heavy metals such as iron, 
manganese, silver, and gold, the origin of geodes, and the 
formation of natural gas and other hydrocarbons. In recognition 
of these discoveries university departments are popping up with 
new names such as geomicrobiology. Some of these startling 
findings challenge our understanding of certain laws of physics 
and thermodynamics as applied to biology, because it appears that 
the nuclei of elements may be altered and recombined so as to 
produce other elements. 

Henry Ehrlich, author of the textbook GEOMICROBIOLOGY said "we're 
still at the very beginning of understanding how microbes shaped 
the planet." (NY Times, 10/15/96). Stephen Jay Gould has written 
with approval and considerable awe over such evidence in his book 
Full House, and cites evidence that microbes in the earth's crust 
and ocean live up to several miles deep in the earth's crust, in 
temperatures up to 650 F, and under pressures up to 265 
atmospheres (Full House, p. 189). Microbes may even outweigh all 
other living matter including trees. As William J. Broad, science 
writer for the New York Times wrote: 

"In hundreds and perhaps thousands of cases, scientists are 
discovering that microbes dwelling up to miles deep in the 
planetary crust are responsible for creating and arranging the 
rocks, seas, gases, metals and minerals that make up the 
Earth's surface." (William J. Broad, "Microbes likely had 
vital role in shaping Earth's outer crust", New York Times, 
Oct. 15, 1996.) 

According to William A. Fyfe, an environmental geochemist at the 
University of Western Ontario, 20 years ago there were about 40 or 
50 compounds that were known to be made or amassed by microbes, 
sometimes as excreta or body parts, just as humans concentrate 
calcium to make teeth and bones. "Today the number is hundreds" 
he said. "Every time we look harder, we find more." (Broad, NY 
Times, ibid.) 

Thomas Gold, eminent scientist at Cornell University, originator 
in 1948 with Hoyle and Bondi of the steady state universe theory 
(which may be making a comeback), and the theory that pulsars are 
neutron stars, has written a recent book that gives significant 
support to the role of microorganisms in geological processes. 
(Gold, The Deep Hot Biosphere (1999) p. 131). He says: 

"Indeed the problem is so great that answers are promoted 
piecemeal-some chemical reactions are proposed for the 
solution and deposition of one metal, and a different set is 
proposed for another. Piecemeal answers are especially 
questionable when there is a group of metals involved, and a 
different path is proposed for each of them., yet they are 
often packed closely together." (p. 132) 

The scientific evidence shows that microbes play a major role in a 
wide variety of geological and paleontological formations, and 
mineral and hydrocarbon deposits, and that they often perform 
these transformations rapidly, that is, within a few years, or 
even in weeks or days. Let's begin by looking at some of the well 
documented roles of microbes in geology. 

Limestone gets its name because of the high percentage of calcium 
or lime in it. Ehrlich's textbook contains a detailed discussion 
and excellent microscopic photos of numerous bacteria, fungi, and 
lichens inhabiting and altering limestone. (3rd Ed., pp. 200-204). 
It appears that microbes also may play a major role in the 
creation of limestone, which I will discuss later. 

PRESERVATION OF FOSSILS. British and French scientists propose 
that microbes are responsible for the preservation of ancient soft 
tissues, by turning them into rock. (Wilby, P.R., Briggs, D.E.G., 
Riou, B., "Mineralization of soft-bodied invertebrates in a 
Jurassic metalliferous deposit," Geology, September, 1996, v. 24, 
no. 9, pp. 847-850). When the bacteria form apatite, the fossil 
is preserved at the subcellular, microscopic level. (Apatite is 
the chief mineral, a form of calcium phosphate, from which our 
bones are composed) "(W)here soft tissues are preserved in pyrite 
[iron sulfide] and other minerals, only their outline usually 
survives. A progressive sequence of fossilization caused by 
microbes appears as follows: apatite [calcium phosphate] calcite 
[calcium carbonate] ± gypsum [calcium sulfate] pyrite [iron 
sulfide] ± chalcopyrite [copper iron sulfide] galena [lead 
sulfide]. Laboratory experiments show that the mineralization of 
soft tissues in apatite occurs within two to four weeks after 
death". (p. 849) (Parenthetical matter [] added). Transformation 
of apatite to other minerals also occurred at an early stage. 
(loc. cit.). 

Petrified Wood. In 1975 Richard F. Leo published his Ph.D. thesis 
at Harvard entitled Silification of Wood. He found that 
silification of wood may occur rather rapidly, such as a wood 
specimen taken by Leo from a spring in Yellowstone Park, Wyoming 
which the author said could not have been in the spring more than 
13 years, since the spring came into being 13 years before as a 
result of an earthquake. The author speculates about the 
mechanism of silification or petrification, and reaches no firm 
conclusions. He did not seriously consider the role of microbes, 
perhaps because it was not until several years later that 
knowledge of the role of microbes in geological processes became 
more widespread. However, he says that the presence of water is 
necessary for the process. Of course water would also be 
necessary for microbes. Leo assumes that silica comes into the 
tree from outside, however, such as from sand deposits in which 
the tree rests. Later experiments using bacteria or yeasts such 
as the residue of beer to cause petrification of wood have 
reported petrification within three years. These experiments used 
wood soaked in beer-making residue and embedded in sand. The 
moisture must be sufficient for the microbes but not so great as 
to cause the wood to rot. Leo points out that "beer, due to the 
malt husk, is essentially a saturated solution of silica," citing 
Iler, 1955 (p. 74). Of course fossilized trees would not have 
been immersed in beer. There is another potential source of 
petrified silica in the wood itself, which I will discuss later, 
and which might better explain why the subcellular structure of 
the wood or of fossils is often preserved than the assumption that 
the silica migrated from outside the wood. 

GOLD AND SILVER. The Serra Pelada is a famous gold field in the 
Amazon jungle, where prospectors have extracted more than 100 tons 
of gold since it was discovered in the early 1980's. Scientists 
concluded that the rich lode was produced by swarms of microbes 
that "concentrated" the gold from soils, rivers, and rocks (Broad, 
supra). Southam and associates made some excellent microscopic 
photos of gold octahedral crystals produced by microbes. In one 
study ionic gold was transformed in several steps by bacteria into 
crystalline octahedral gold containing 85% gold. In the latter 
two stages the gold increased from 75% to 85%, while sulfur 
declined from 9% to 1%, and phosphorus decreased from 14% to 10%. 
(Gordon Southam and Terrance J. Beveridge, "The occurrence of 
sulfur and phosphorus within bacterially derived crystalline and 
pseudocrystalline octahedral gold formed in vitro," (Geochimica et 
Cosmochimica Acta, Vol. 60, No. 22, pp. 4369-4376, 1966). 

The roughly 13% increase in gold within a short period of time, 
accompanied by comparable decreases in S and P is an interesting 
finding that may reflect a complex transmutation into gold, 
possibly involving sulfur and phosphorus. When the experiment was 
extended to four weeks at room temperature, or when the 
temperature was raised from room temperature to 60 C or 90 C, the 
octahedral gold was increased. The ionic gold used at the start 
of the experiment killed the bacteria within seconds, and the 
bacteria had to be replenished. Octahedral gold is an important 
constituent of placer gold, which forms nuggets. The octahedral 
gold contains spheres representing the bacteria. The authors 
state: "The gold has increased in size one thousandfold and now 
dominates the bacterial cells they were once inside." (p. 4528) 
(Southam and Beveridge, "The in vitro formation of placer gold by 
bacteria", Geochimica et Cosmochimica Acta, Vol. 58, No. 20, pp. 
4527-4530, 1994). (Southam is a biologist at Northern Arizona 
University, and Beveridge is a microbiologist at University of 
Guelph, Ontario, Canada. 

Thomas Gold points out that gold in mineral deposits is 
concentrated "a million or even a hundred million times greater 
than in the source of composite from which it came". (Ibid., p. 
131). He says: 

"Indeed the problem is so great that answers are promoted 
piecemeal-some chemical reactions are proposed for the 
solution and deposition of one metal, and a different set is 
proposed for another. Piecemeal answers are especially 
questionable when there is a group of metals involved, and a 
different path is proposed for each of them., yet they are 
often packed closely together." (p. 132) 

It appears that silver may also be produced by microbes. I took a 
photo of a rock at the Colorado School of Mines museum. The 
silver deposit in the rock is shaped like deposits produced by 
lichens or other microbes. That would be consistent with 
Ehrlich's and Southam's findings regarding gold deposits and 
microbes. 

Probably the high pressures (up to 265 atmospheres) and 
temperatures (up to 650 F) deep within the earth provide added 
energy that helps cause such reactions, as Gold believes, although 
he says that the cost to do studies at such pressures and 
temperatures is rather prohibitive. These pressures also allow 
water to be liquid at temperatures far exceeding the boiling 
point, and far exceeding 451 degrees F, which is the temperature 
at which a match will cause a piece of paper to catch on fire. 
Such a liquid or flow state appears to be essential for life, 
whereas temperatures and pressures may vary widely. 

Gold also says: 

"It is generally believed that microbes can build concentrated 
deposits of a wide variety of minerals" (ibid., p. 138, citing 
Barry S.C. Leadbeater and Robert Riding, eds. 
Biomineralization in Lower Plants and Animals.", Clarendon, 
Oxford, England, p. 4; also Lynn Margulis and Dorion Sagan, 
What is Life? Simon and Schuster, N.Y., 1995. 

Here are a few more examples of the hundreds of other mineral 
deposits that the evidence indicates were formed by microbes: 

Magnetite; phosphates; carbonates; sulfates; metal sulfides 
(pyrite, galena [lead sulfide]); quartz; clay; graphite; etc., 
copper ores, iron ore, vanadium, nickel, etc. 

Natural gas, hydrocarbons, and petroleum. Anna M. Martini and co- 
workers at the University of Michigan and Martin Schoell of 
Chevron studied deposits of methane in the Antrim shale along the 
northern margin of the Michigan basin at depths of less than 600 
meters and found evidence that significant volumes of bacterial 
gas were generated, supplementing previous findings that methane 
of bacterial origin is "ubiquitous in marine and fresh water 
sediments," though mainly at depths of several kilometres in 
basins that had high sedimentation rates. Anna M. Martini, et al., 
"Microbial generation of economic accumulations of methane within 
a shallow organic-rich shale," (Nature, Vol. 383, 155-158, Sept. 
12, 1996). The gases from the Antrim shale vary from pure methane 
to approximately 5% hydrocarbons with two or more carbon atoms. 
The authors conclude: 

"Non-conventional gas resources, such as coal beds and organic 
rich shales have largely been attributed to thermogenic (i.e. 
non-microbial) processes, yet they may contain far more 
microbial gas than previously believed" (ibid., p. 157). (that 
is, microbes produce a lot of methane and some longer chain 
hydrocarbons) 

RADIOACTIVITY. Scientists have found bacteria that can withstand 
lethal levels of radioactivity. One example is a bacterium that 
can support ten million roentgens (x-ray units of measure) for 
eight hours, or 20,000 times the mortal dose for humans of 500 
roentgens. This bacterium, of the Pseudomonas type, was discovered 
in 1958 in Los Alamos in the water of a nuclear reactor. "It 
liked the medium so much that it reproduced every twenty minutes." 
(Kervran, Swan House Pub., p. 111). In a reactor in Lucas 
Heights, Australia, there were two million bacteria per cubic cm. 
However, only 1,000 of these bacteria were left when the heavy 
water came out of the reactor. Micrococcus radiodurans resists 
3,000 times the mortal dose for mammals (ibid., p. 113). 

A research study showed that radioactive mercury 203 diminished 
much more rapidly than expected due to the action of bacteria. 
Radioactive mercury 203 has a half life of 46 days. However, 
Magos and co-workers showed that after a period of 16 hours of 
normal degradation there was thereafter a much more rapid 
disappearance of mercury 203 which was very great at 48 hours. 
The researchers reasoned that microbes might have caused the 
excess diminution because the great increase only occurred after 
an "incubation" period of about 16 hours. (Kervran, Beekman Pub., 
pp. 78-79; L. Magos, Tuffrey and T.W. Clarkson, "Volatilization of 
Mercury by Bacteria," Brit. J. Ind. Med., Oct. 1964, pp. 294-98). 
Kervran notes that including toluene or penicillin in the medium 
prevents any excess diminution of mercury, and that the term 
"volatilization" that was assumed by the researchers to explain 
the diminution is unlikely given that mercury boils at 360 degrees 
C and its vapor pressure is very low at even at 40 to 50 degrees 
C, whereas the experiments were conducted at 20 degrees C (68 F). 
Also, certain bacteria were very active in the media (Kervran, 
Beekman Pub. pp. 78-81; Swan House Pub., 111-113). 

The fact that bacteria can withstand enormous temperatures, 
pressures, and levels of radioactivity makes it more probable that 
bacteria may be found in comparable conditions on other planets, 
meteorites, comets, and moons, thus supporting the conclusions of 
some scientists that microbes were found on rocks from Mars, the 
Allende meteorite that fell in Mexico in 1967, and rocks from the 
moon, as Thomas Gold asserts. Actually, the eminent Fred Hoyle 
long ago advanced the position that microbes live in such 
conditions and may be transported to other bodies by comets, etc. 
A microscopic photo was taken of apparent bacteria in the Allende 
meteorite in Mexico. 

Earl Staelin 
To be continued 
************************************************************ 

WATER ON MARS? 
By Wal Thornhill 

Planetary scientists are busy looking for evidence of water on 
Mars in support of plans to send robotic and, eventually, manned 
missions to the red planet. Water is a key ingredient in the 
search for signs of extraterrestrial life. Some scientists 
speculate that life may have once existed on Mars because a few 
massive channels there suggest floods of copious liquid surface 
water in the planet's dim past. Also, the possibility of life is 
suggested by the presence of carbon dioxide as a major constituent 
of the thin atmosphere. 

The scientific community has shifted its earlier view of Mars 
dramatically. Instead of stories about the cold desert planet, the 
popular press now prints headlines such as: "Flood Carves Instant 
Grand Canyon." The situation is ripe for seeing only what is 
already believed. This bias shows in the language when channels 
are identified unequivocally as fluvial (carved by flowing water) 
and of late Noachian age (between 3.5 and 3.7 billion years old), 
the very name invoking images of a universal flood. 

The thesis presented on this website tells a completely different 
history of Mars, based upon the electrical nature of the solar 
system and recent chaotic orbital behavior. It may seem outrageous 
to propose a completely different Mars about 10,000 years ago, 
instead of 3,500 million years ago in the conventional story. 
However, the dating techniques used by geologists rely on a belief 
in fictional and endlessly adjustable planetary evolution stories 
a different story for each planet. These stories have proven to 
be totally non-predictive. Good science requires accounting for 
as much of the relevant evidence as possible. Instead of 
working forward from a set of beliefs about the past, we should 
first assemble all the data we can, including that from the 
stories told by ancient people about the behavior of objects they 
saw in the sky. A forensic method can glean useful information 
from these archaic stories, rituals, and art that can help 
distinguish between alternative explanations for present 
conditions. 

The results of this forensic research by a very few adventurous 
scholars are unequivocal, unexpected and disturbing. If we could 
see it, our prehistoric sky would stupefy us with its 
unfamiliarity. Mars and Venus moved close to the Earth and met in 
apparent combat wielding thunderbolts. The spectacular patterns of 
interplanetary lightning were commemorated globally in 
petroglyphs, monumental works and cultural traditions. Our 
prehistoric ancestors remembered the Earth's encounters with a 
furious Mars, "the god of war," as the archetypal "doomsday." That 
memory survives to this day in our cultures and religions, its 
true meaning almost universally unrecognized. We do not want to 
know that our beautiful Earth can be unsafe. We accept 
palaeontologists' stories about global extinction events provided 
they happened in the dim and distant past. Modern doomsayers, as 
if tuned into the ancient fears, try to arouse us by stories of 
imminent impacts. But those stories are based on the geologists' 
misunderstanding of impacts. Global devastation requires an 
encounter between planets, not puny asteroid impacts. The evidence 
for planetary electrical encounters is sufficiently detailed and 
extensive to fill several forthcoming books. 

Being a small body, Mars suffered terribly in its planetary 
electrical exchanges. It lost most of its atmosphere in the 
process and gained a little in return. So present day measures of 
water and carbon dioxide on Mars do not represent billions of 
years of evolution. Indeed, the dominant constituents of its 
atmosphere, carbon dioxide and nitrogen, could have been predicted 
from the global accounts of the entanglement of Mars with the 
distended atmosphere of Venus. Also, it has been known since the 
first space probes descended into the infernal atmosphere of Venus 
that the measurements of isotopic ratios in its atmospheric gases 
contradict the standard evolutionary model of planet formation. 
The reason is that interplanetary discharges are powerful enough 
to cause nuclear transformations. In particular, they are copious 
generators of neutrons. So the anomalously high levels of the 
heavy isotopes of carbon (13C), nitrogen (15N) and hydrogen 2H, in 
the Martian atmosphere may be understood simply as due to neutron 
capture in the gases stretching between Mars and Venus during one 
of their celebrated battles. 

So, what are we to make of the orthodox dating of the channels on 
Mars to almost 4 billion years ago? Relative dating of surface 
features relies upon comparisons of crater counts on the surfaces 
of Mars and other bodies. Radioactive clocks are then used to pin 
down the age of surface rocks. We have for that purpose rock 
samples from the Moon and a small number of meteorites identified 
as originating from Mars. But if the initial states of the rocks 
are unknown and the clocks can be upset by energetic electrical 
discharges, geologists are left with little else to date the 
surface features of Mars other than to count craters. And that is 
a method based on two crucial and erroneous assumptions: 

The first assumption is that the solar system has run like 
clockwork for 5 billion years. That has allowed a fictitious early 
history to be written about planets being hit by leftovers from 
their afterbirth. The impacts had to be late enough that the 
planets could record them on a solid surface, so it is called the 
"late heavy bombardment." Crater statistics led to a need for 
another episode, called the "post late heavy bombardment." This 
"history" is a complex fiction because (1) the "accretion by 
impact" model of planet development has not been shown to work; 
(2) the source of objects responsible for the cratering record 
observed on solar system bodies remains an unsolved problem. (The 
"Oort cloud" of comets is postulated as one source of ammunition 
for pockmarking planets. However, the number of comets seen does 
not support the existence of such hypothetical "builder's rubble" 
of the solar system. Nor does the theory make any sense.); and (3) 
random impacts do not explain either the detailed pattern of 
cratering nor the heavily cratered southern hemisphere and much 
smoother northern hemisphere of Mars. 

The second assumption is that planetary craters are caused by the 
impacts of comets and asteroids. This assumption is clung to in 
the face of contradictory evidence. Researchers have admitted that 
it has not been possible to reproduce the features of most 
planetary craters with either impacts or explosions. So it is 
simply assumed that the craters are a result of impacts, and their 
features are used in an attempt to understand impact cratering! 
That is circular thinking, not science. 

So what can be said of water on Mars in its earlier history? In 
the real story of Mars, the god of war, its pre-battle surface 
environment was likely to have been much more benign and Earth- 
like than it is today. On that basis I predict there was liquid 
water on the surface of Mars within the time of modern homo 
sapiens and that there is a good chance of finding fossils of 
complex life forms on Mars. 
---------------------------------------------------------------- 

Keeping this in mind, let us look critically at this report from 
the Smithsonian researchers: 

June 20, 2002 
Smithsonian National Air and Space Museum 

Large Former Lake, Catastrophic Flood Identified on Mars 

Geologists at the Smithsonian's National Air and Space Museum have 
discovered a large former lake in the highlands of Mars that would 
cover an area the size of Texas and New Mexico combined, and which 
overflowed to carve one of that planet's largest valleys. The 
findings will appear in the June 21 issue of the journal Science. 

The flood channel, Ma'adim Vallis, is more than 550 miles long and 
up to 6,900 feet deep, making it larger than Earth's Grand Canyon. 

"Imagine more than five times the volume of water in the Great 
Lakes being released in a single flood, and you'll have a sense of 
the scale of this event," said Ross Irwin, a geologist in the 
museum's Center for Earth and Planetary Studies (CEPS) and the 
paper's lead author. 

Mars is now a cold desert planet but its many dry valleys could 
indicate that water once flowed on its surface. Recent results 
from the Mars Odyssey spacecraft have found evidence of water 
trapped in the near surface of the polar regions. 

"The size of this lake -- 1,400 miles long -- suggests Mars was 
warmer and wetter than previously thought," said Robert Craddock, 
a CEPS geologist and co-author of the paper. Former lakes are 
considered the most likely places to preserve the record of any 
past Martian life. Calm water would allow sediments to be 
deposited slowly, preventing small organisms from being destroyed. 

The source of water to carve the flood channel had long been a 
mystery to scientists, who had known very little about Mars' 
topography prior to the Mars Global Surveyor mission, which has 
been orbiting Mars since 1997. 

Detailed elevation data from the Mars Global Surveyor shows the 
large valley originated nearly full-size at a ridge, much like the 
spillway of a dam. Late in the lake's history, rising water levels 
overflowed the lake basin rim, releasing the huge flood as the 
river cut into this former dividing ridge. What remained was "some 
of the best geological evidence for a lake found to date on Mars, 
including clear indications of the former shoreline," Irwin says. 

Two other smaller lake basins were identified in the region by 
paper co-author Alan Howard, a geologist at the University of 
Virginia. All three lakes shared the same water level prior to the 
flood, indicating the possibility of an ancient water table and 
suggesting the locations of other dry lake basins on Mars. Such 
information could be important in determining where to land 
robotic probes in coming years. 

CEPS is the scientific research unit within the Collections and 
Research Department of the National Air and Space Museum. CEPS 
performs original research and outreach activities on topics 
covering planetary science, terrestrial geophysics, and the remote 
sensing of environmental change. END OF REPORT
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Comment: The geologists have not "discovered" a lake on Mars in 
the real sense of the word. They have discovered a cutoff level of 
valley networks, based on topographical maps derived from the Mars 
Orbiter Laser Altimeter (MOLA) data. There appears to be an 
"abrupt transition from bedrock to less resistant sedimentary 
materials" at the 1100-metre contour. So this "shoreline" need 
only be reflecting the different response of the surface material 
to whatever erosive force shaped the area. 

The major problem faced by geologists trying to explain huge 
valleys on dry and freezing Mars is to find a prodigious source of 
liquid water. With few signs of feeder streams or catchment areas, 
the various proposals have all required an underground source of 
water with unexplained episodes of heating. This paper is the 
first detailed proposal for a large surface reservoir of liquid 
water, and it requires a completely different atmospheric and 
temperature regime on Mars from that found today. For that reason, 
geologists push the event back into some imagined past epoch, 
called the "Noachian" era, ignoring the fact that the channels 
look new. 

It is surely premature to declare that a former lake has been 
discovered on the basis of a "shoreline" and the identification of 
a single channel, Ma'adim Vallis, as an overflow channel that was 
carved by a catastrophic flood from that putative lake. An 
overflow of such magnitude over sedimentary material would usually 
be expected to produce a braided stream of many channels. This is 
particularly so given the cratered terrain, where crater ramparts 
should divert the flood. Instead of that, Ma'adim Vallis is 
noteworthy for the way it breaches crater walls as if they never 
existed. Even more damaging for the water erosion story is the 
fact that the channel bed itself does not show the forms expected 
of flowing water! 

Shown here in greater detail is Ma'adim Vallis, the channel picked 
out in blue in the earlier picture. It is about 900 km long and 
varies in width from about 8 km to some 25 km near the mouth. Note 
that the flood is said to have originated at the bottom of the 
picture, where the lake is supposed to have breached an ancient 
crater rim. The expectation would be that the channel would be 
largest there but that is not the case. In fact it widens and 
deepens "downstream." The morphology of Ma'adim Vallis is 
precisely that of a sinuous rille. See also 'Mars and the Grand 
Canyon.' at 

Ma'adim Vallis was formed by surface lightning, streaking across 
Mars toward Gusev Crater. Gusev crater is the 150 km diameter 
crater at the top of the valley. 

This channel is supposed to be incredibly old -- 3,500 million 
years! Yet it looks as if it was carved yesterday. If the craters 
are formed in the same flurry of electrical discharge activity 
across this hemisphere of Mars then the large crater seen 
straddling the channel may have been formed shortly before the 
rille was carved through it by the surface discharge. 

Full article with photos of Martian rilles and laboratory 
experiments can be found at: 

Cathode arcs focus on local sharp high points. Having formed a 
crater, the tendency is then for the arc to jump to the rim of the 
new crater. By this means, continuous channels, composed of 
overlapping circular craters, may be cut into a surface. The edges 
of such a channel have a characteristic "cookie cutter" or 
scalloped appearance. This effect can be seen in the Ma'adim 
Vallis tributaries at lower center and top center in the picture. 
A small crater centered on the rim of a large crater is seen at a 
glance in images of any cratered planetary surface. It is an 
observation that impacts cannot explain. The two dissected craters 
at the entrance point of Ma'adim Vallis to Gusev crater show this 
hierarchical effect in relation to the Gusev crater. 

So, what is the story of the formation of Ma'adim Vallis? An arc 
cutting Gusev crater will sap electrons from the surrounding 
terrain by creating a strong radial electric field that begins to 
rip electrons from the solid surface. When breakdown begins, a 
lightning bolt tears across the surface, blasting soil and rock to 
either side of its sinuous path. A large proportion of the 
excavated material is impelled electrostatically to follow the 
main discharge toward space. Pieces not pulled into space would 
fall back in a more or less random scattering all over Mars. That 
explains why there is little evidence of deposition inside Gusev 
Crater from a channel that is larger than the Grand Canyon. It is 
also the reason why every Mars lander has returned a vista of 
rubble that extends to the horizon. 

Mars has many giant channels like Ma'adim Vallis. One of the 
mysteries of these channels is the prevalence of transverse 
ridges, or so-called "sand dunes." On a planet with practically no 
atmosphere that description seems far-fetched. Here we show an 
excellent example from the floor of the 700 km long Nirgal Vallis. 

On another Martial rille, Nirgal Vallis, the inner channel is the 
path followed by the lightning discharge and is somewhat more 
sinuous than the excavated channel. The floor of the main channel 
is crisscrossed with lines conventionally interpreted as "dunes". 
These "dunes" turn the bend to follow the inner channel. Wind 
would not be expected to do that. 

The "exploding wire" experiment is deemed to be the closest thing 
to real lightning achievable in the laboratory. A thin wire is 
suspended and a powerful electric discharge sent through it. The 
wire is instantly vaporized and coronal filaments radiate into the 
air from the plasma discharge channel. It is the radial discharges 
of the corona that provide the clue to the origin of the "sand 
dunes" on Mars. It is well known that lightning passing through 
dry sand will form crumbly, glassy tubes of welded sand, known as 
fulgurites. It seems likely that the sand dunes in the Martian 
valleys are ridges of glass! They were formed by a corona 
discharge from the main lightning stroke. 

Photo of exploding wire experiment at. 
Courtesy of Ed Bondarenko, Telstra Labs, Melbourne, Australia. 

The width of the Martian channel seems to be influenced by the 
width of the corona and depth of the discharge, which in turn is 
dependent on the conductivity and nature of the near-surface rock. 

[Photo caption] A "gully" in Gorgonum Chaos. The image is about 3 
km square. Notice that a little liquid seems to have seeped from a 
stratum near the top of the south-facing channel wall. 

A narrow lightning stroke at depth produces a V-shaped explosion 
channel. A broad corona in poorly conducting soil seems to produce 
a flatter floored channel. There are a few examples where a little 
water seems to have trickled down channel walls from a near- 
surface layer. That may be misleading because it could be an 
artifact of the electrical discharge, which seems to introduce an 
asymmetry in the pattern of erosion in opposite walls. See 
Gorgonum Chasma and also the asymmetric erosion of the north and 
south walls of Valles Marineris. 
------------------------------------------------------------------ 

So if the huge channels on Mars were not carved by catastrophic 
floods in the remote past, what are the chances of finding 
subsurface water on Mars now? 

Although the giant channels on Mars were not carved by water, 
there is better evidence, apart from the small seepage channels, 
that Mars had more water in the past. It comes from the peculiar 
appearance of some Martian craters, where mud seems to have flowed 
away from the crater's rim. It is not the sort of thing that can 
be explained by an explosive impact. However, it is expected from 
an electric arc impinging on a moist anode surface. In the 
experiment shown here, an arc from a suspended cathode has struck 
a moist clay anode, representing the Martian surface. Unlike the 
jumping cathode arc, the anode arc "sticks" to the spot and 
rotates to form a circular scar, while water comes to the clay 
surface and flows gently away from the rim of the scar. 

[photo caption] An arc striking a moist clay anode. The clay has 
become quite wet surrounding the arc scar. Experiment courtesy of 
Rod Browitt. 

[photo caption] Here is an example from Mars. The larger, unnamed 
crater is 10 km across. Notice the rotary terracing effects of the 
spinning arc in the crater floor and the tendency in large craters 
to leave a central peak relatively untouched. An impact cannot 
explain these features, nor the lack of damage caused by one 
crater to the other. Ballistic emplacement of the ejecta has been 
ruled out by geologists. These "rampart" craters are widely 
distributed on Mars, which indicates a former "moist" environment 
over the entire planet. 

Recently, the Mars Odyssey spacecraft has been measuring neutrons 
from the atomic debris caused by cosmic rays smashing atoms as 
they penetrate the Martian crust. From the neutron energies it is 
possible to determine the presence and rough depth of hydrogen 
atoms beneath the surface. The assumption is made that any 
hydrogen signal is due to subsurface mineral-bound water. In the 
diagram below, the blue areas returned the stronger hydrogen 
signals. As expected from the (as yet untold) recent history of 
Mars, the south Polar Regions have the highest abundance. There is 
a caution to be added however. As a report in Science* noted, "The 
hydrogen signature extends willy-nilly beyond the lander targets 
across any number of geologic terrains." 

The regions are "very hard to reconcile with what we know about 
geology or topography," says planetary scientist James Bell of 
Cornell University. "They don't fit the distribution of particular 
rock types, rock abundance, dust, or even atmospheric water vapor, 
notes planetary scientist Bruce Jakosky of the University of 
Colorado, Boulder." 

Plasma arcs are the most efficient means known for implanting ions 
into a solid surface. That could account for the lack of 
correlation with the geology. The problem facing NASA may well be 
that the hydrogen signature in the lower latitudes is mainly from 
implanted hydrogen ions and not from water. 

Summing up: With the available evidence and some insights into the 
recent history of the solar system it is possible to confidently 
answer some of the questions about Mars: 

* YES, there was some water, and probably life too, on Mars in the 
recent past. However, the water was mostly stripped off along with 
the atmosphere. There is abundant evidence of catastrophic winds, 
electrical erosion and hemispheric differences arising from that 
process. 

* The carbon dioxide "ice caps" and remnant atmosphere are from an 
exogenous source - Venus. 

* And NO, the giant channels on Mars cannot be used as evidence of 
a "Noachian" flood time on early Mars. When the history of Mars is 
finally told, the irony in the use of that name will become clear. 
------------------------------------------------------------------ 

In an editorial, "Where's the sparkle?" in New Scientist 8 June 
2002, NASA is accused of having run out of things to say. The 
story of water on Mars has been heard too many times, even though 
there was some new information. It "only served to strengthen the 
cynical view of NASA as an agency obsessed with spin and devoid of 
new ideas and goals." But to have really new ideas and goals 
requires new people and NASA is firmly in the grip of "old" 
experts. As Max Plank wrote ruefully, "An important scientific 
innovation rarely makes its way by gradually winning over and 
converting its opponents. What does happen is that its opponents 
gradually die out, and that the growing generation is familiarised 
with the ideas from the beginning."** 

Meanwhile, NASA's Cassini mission to Saturn is due to arrive there 
in 2004. Be prepared for some BIG surprises, particularly 
concerning Saturn's giant moon, Titan. You see, the primordial and 
greatest god of old was Saturn, not the Sun. Titan is a very close 
relative of the Earth, Mars and Venus. Sorry NASA, life's too 
short to wait for you! 

*Science 2002 June 14; 296: 1962 
** Max Planck, (1858-1947) from Scientific Autobiography, 1949. 

(c) Wal Thornhill 2002 
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