Can Liquid Water Still Exist On Mars
Fly-by view across a
"submerged" Isidis Planitia to the Hesperia Planum. The
Du Martheray crater in front... Image by Kees
Veenenbos using MOLA elevation data |
Moffett Field - March 28, 2001
NASA Astrobiology Institute
In 1998, NASA's Associate Administrator Wesley
Huntress, Jr., stated, "Wherever liquid water and chemical energy are
found, there is life. There is no exception."
Could there, then, be life on Mars? In the mid-1970s, the Viking Lander
mission's Gas Exchange Experiment detected strong chemical activity in the
martian soil. Liquid water seems to be the one element needed for the
equation of life on Mars. The presence of water there, however, is still
hotly contested.
Many scientists believe that liquid water does not and cannot exist on
the surface of Mars today. Although surface water may have been plentiful
in Mars' past, they say, the current conditions of freezing temperatures
and a thin atmosphere mean that any water on Mars would have to be deep
underground. Moreover, if any water ice existing on Mars were somehow
warmed, it still wouldn't melt into water. The thin martian atmosphere
instead would cause the ice to sublime directly into water vapor.
But Dr. Gilbert Levin of Spherix, Inc., and his son, Dr. Ron Levin of
MIT's Lincoln Laboratory, believe differently. They say that liquid
water-in limited amounts and for limited times-can exist on the surface of
present-day Mars. They have based their theory on data collected from the
Viking landers and on the 1997 Mars Pathfinder mission.
This father-son team has suggested a diurnal water cycle on Mars: water
vapor in the air freezes out by night, then during the day the ice melts.
As the day progresses, the heat of the Sun causes this liquid water to
evaporate back into the air.
You may like to open.
the science paper by Drs. Gilbert Levin and Ron Levin this article
is based upon. This paper contains a series of charts that explain
the proposed process by which water can at times be liquid on Mars.
Click
here and let the page load, then scroll down past the text for
series of eight charts detailing the Levins' proposed water cycle. |
It has already been established from Viking photographs that a thin frost
does form overnight on certain areas of the martian surface. Unlike many
scientists, the Levins believe that this frosty layer does not instantly
revert back into water vapor when the Sun rises. They suggest that, in the
early hours of the martian morning, the atmosphere more than one meter
above the martian surface remains too cold to hold water vapor. So the
moisture stays on the ground.
Data from the Mars Pathfinder support this theory, as the Pathfinder
temperature readings noted that temperatures one meter above the surface
were often dozens of degrees colder than the temperatures closer to the
ground.
This layer of cold air, say the Levins, provides a form of insulation,
trapping the water moisture below. Since the atmosphere is too cold to
hold the water as vapor and the ground is warm enough to melt the ice, the
water melts into a liquid. This liquid water, the Levins believe, remains
on the surface until the temperature of the atmosphere rises enough to
allow the water to evaporate. In this way, they argue, the martian soil
becomes briefly saturated with liquid water every day.
"The meteorological data fully confirm the presence of liquid
water in the topsoil each morning," says Gilbert Levin. "The
black-and-white as well as the color images show slick areas that may well
be moist patches."
Such a scenario is certainly possible, admits Christopher McKay. McKay
is a planetary scientist at NASA Ames Research Center in Mountain View,
CA, and a member of the NASA Astrobiology Institute.
"At the surface the frost may melt to form a very short-lived
layer of liquid," says McKay. "The experiments show that this is
the case." But, he cautions, "how long it persists is not yet
accurately determined.
"There have been several attempts to look at the problem of frost
evaporation and melting on Mars theoretically," says McKay. But
Levin's analysis, he says, is "badly flawed. The way to address this
question," he says, "is with experiment."
The Levins look to tests conducted in Death Valley, CA, for support of
their theory. Soil samples taken from the top one to two millimeters of
the Californian sand dunes and analyzed by soil scientists from NASA's Jet
Propulsion Laboratory were reported to contain 0.9% moisture, comparable
to the moisture levels found in the martian soil by the Viking mission.
These desert samples from California also contained aerobic
microorganisms. No clear evidence has yet been found, however, that there
is life in the topmost layer of the martian soil.
Mars may, indeed, contain such forms of microorganic life. The Levins
point to a study published in the Federation of European Microbiological
Societies Reviews in 1997 by Elena Vorobyova, et al., entitled "The
Deep Cold Biosphere: Facts and Hypothesis." This study reported that
permafrost conditions provide a constant and stable environment to permit
microbial communities to survive for millions of years.
The Levins cite this research as direct evidence for adaptive
physiological and biochemical processes in microorganisms during long
exposure to cold. While these findings refer to terrestrial microorganisms,
the Levins believe they might also apply to Mars.
McKay does not believe these analogies to terrestrial environments
prove anything about Mars, however. "Mars is still much drier and
much colder than even the Atacama Desert in Chile or the dry valleys of
Antarctica," argues McKay. "And Death Valley is not that dry. It
rains there 25 millimeters a year."
Gilbert Levin is a long-time proponent of life on Mars. He worked on
the Viking missions in the mid-1970s and steadfastly believes that the
Viking Lander's Labeled Release (LR) experiment proved that primitive life
does exist on present-day Mars.
The LR experiment dropped liquid nutrient into a sample of martian soil,
then measured the gases that were released by the mixture. If martian
bacteria had consumed the nutrients and had begun to multiply, certain
gases would have been released. When the LR experiment was conducted on
both Viking Landers, some of the gases emitted seemed to suggest that
microbes were ingesting the released nutrients. But, overall, the results
were ambiguous.
Many in the scientific community believe that the LR results can be
explained non-biologically. One such explanation is that the LR experiment
showed the surface of Mars to contain oxides. When the nutrients mixed
with the oxides, a chemical reaction-not a biological one-occurred.
Moreover, these oxides would actually prevent life from forming on the
martian surface.
Gilbert Levin isn't swayed by this reasoning. After examining all the
non-biological possibilities and looking at the new findings about life in
extreme environments on Earth, Levin now firmly believes that the LR
experiment did find microbial life on Mars.
His new model for the formation of liquid water, he argues, "removes
the final constraint preventing acceptance of the biological
interpretation of the Viking LR Mars data as having detected living
microorganisms in the soil of Mars. It comes at a time when a growing body
of evidence from the Earth and space are supporting the presence of life
not only on Mars, but on many celestial bodies."
For McKay, the Viking experiments do not prove-or even suggest-that
life could exist on the surface of Mars. "I support a chemical
explanation for the Labled Release experiment and the other Viking
instruments, such as the Gas Chromatograph/Mass Spectrometer and the Gas
Exchange experiment," he says.
The Gas Chromatograph/Mass Spectrometer (GCMS) was designed to measure
organic compounds in the martian soil. Organic compounds are present in
space (for example, in meteorites), but the GCMS found no trace of them on
the surface of Mars. Gilbert Levin believes, however, that the GCMS
instrument sent to Mars could easily have missed biologically significant
amounts of organic matter in the soil, as it had in a number of tests on
Earth.
The Gas Exchange (GEX) experiment submerged a sample of martian soil in
a nutrient mixture, and incubated the soil for 12 days in a simulated
martian atmosphere. Gases emitted by organisms consuming the nutrients
would have been detected by the gas chromatograph.
While the GEX experiment did detect some gases, it also got results
with the control sample-soil that had been heated to sterilize it of any
possible life. In other words, non-biological processes may have been at
work. Subsequent laboratory experiments on Earth demonstrated that similar
results were obtained when water was added to highly-reactive oxidizing
compounds, such as the oxides or superoxides now believed to be present in
martian soil.
"A biology explanation [for the Viking test results] is
inconsistent, ecologically, with what we know about Mars' surface
environment," says McKay.
What Next?
In 2003, NASA will send two rovers to Mars to hunt for signs of water
in the rocks and surface soil. In the same year, the European Space Agency
will launch Mars Express, which will include a lander. The Lander, dubbed
Beagle 2, will contain a scientific payload dedicated to detecting signs
of biogenic activity on Mars-the first such payload to be sent to Mars
since Viking.
This article was written by a staff writer at the NASA
Astrobiology Institute. - published on http://www.spacedaily.com/news/mars-water-science-01e.html
- April 26, 2001 |
