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Mars Ocean Hypothesis


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The blue region of low topography in the Martian northern hemisphere is
hypothesized to be the site of a primordial ocean of liquid water.

The *Mars Ocean Hypothesis* states that nearly a third of the surface of
Mars was covered by an ocean of liquid water early in the planet’s
geologic history .^[1] This primordial ocean, dubbed Oceanus Borealis,^[2]
would have filled the Vastitas Borealis basin in the northern hemisphere,
a region which lies 4-5 km (2.5-3 miles) below the mean planetary
elevation, at a time period of approximately 3.8 billion years ago.
Evidence for this ocean includes geographic features resembling ancient
shorelines, and the chemical properties of the Martian soil and
atmosphere. Early Mars would require a warmer climate and thicker
atmosphere to allow liquid water to remain at the surface.^[3]


Contents

[hide ]

* 1 Observational Evidence 
* 2 Theoretical issues 
o 2.1 Primordial Martian climate 
o 2.2 Chemistry 
o 2.3 Fate of the ocean 
* 3 Alternate explanations 
* 4 See also 
* 5 References 
* 6 Further reading 


[edit ] Observational Evidence

There are several physical features in the present geography of Mars that
suggest the existence of a primordial ocean. Networks of gullies that
merge into larger channels imply erosion by a liquid agent, and resemble
ancient riverbeds on earth. Enormous channels, 25 km wide and several
hundred meters deep, appear to direct flow from underground aquifers in
the Southern uplands into the Northern plains.^[3] Much of the northern
hemisphere of Mars is located at a significantly lower elevation than the
rest of the planet (the Martian dichotomy ), and is unusually flat. Along
the margins of this region are physical features indicative of ancient
shorelines.^[2] Sea level must follow a line of constant gravitational
potential. After adjustment for polar wander caused by mass
redistributions from volcanism, the Martian paleo-shorelines meet this
criteria.^[4] The Mars Orbiter Laser Altimeter (MOLA), which accuratly
determined the altitiude of all parts of Mars, found that the watershed
for an ocean on Mars covers three-quarters of the planet.^[5]


The unique distribution of crater types in the Vastitus Borealis below
2400 m elevation suggest erosion that involved sublimation , and an
ancient ocean that would have encompassed a volume of 6 x 10^7 cubic
kilometers.^[6]

Recent research published in the Journal of Geophysical Research —
Planets, shows a much higher density of stream channels then formerly
believed. Regions on Mars with the most valleys are comparable to what is
found on our Earth. In the research, the team developed a computer program
to identify valleys by searching for U-shaped structures in topographical
data. ^[7] The large amount of valley networks strongly supports rain on
the planet in the past. The global pattern of the Martian valleys could be
explained with a big northern ocean. A large ocean in the northern
hemisphere would explain why there is a southern limit to valley networks;
the southernmost regions of Mars, located farthest from the water
reservoir, would get little rainfall and would develop no valleys. In a
similar fashion the lack of rainfall would explain why Martian valleys
become shallower as you go from north to south. ^[8]


[edit ] Theoretical issues


[edit ] Primordial Martian climate

The existence of liquid water on the surface of Mars requires both a
warmer and thicker atmosphere . Atmospheric pressure on the present day
Martian surface only exceeds that of the triple point of water (6.11 hPa)
in the lowest elevations; at higher elevations water can exist only in
solid or vapor form. Annual mean temperatures at the surface are currently
less than 210 K, significantly less than what is needed to sustain liquid
water. However, early in its history Mars may have had conditions more
conducive to retaining liquid water at the surface.

Early Mars had a carbon dioxide atmosphere similar in thickness to
present-day earth (1000 hPa).^[9] Despite a weak early sun , the
greenhouse effect from a thick carbon dioxide atmosphere, if bolstered
with small amounts of methane ^[10] or insulating effects of carbon
dioxide ice clouds^[11] , would have been sufficient to warm the mean
surface temperature to a value above the freezing point of water. The
atmosphere has since been reduced by sequestration in the ground in the
form of carbonates through weathering,^[9] as well as loss to space
through sputtering (an interaction with the solar wind due to the lack of
a strong Martian magnetosphere).^[12] ^[13]

The obliquity (axial tilt ) of Mars varies considerably on geologic
timescales, and has a strong impact on planetary climate conditions.^[14]


[edit ] Chemistry

Consideration of chemistry can yield additional insight into the
properties of Oceanus Borealis. With a Martian atmosphere of predominantly
carbon dioxide, one might expect to find extensive evidence of carbonate
minerals on the surface as remnants from oceanic sedimentation. An
abundance of carbonates has yet to be detected by the Mars space missions.
However, if the early oceans were acidic, carbonates would not be able to
form.^[15] The positive correlation of phosphorus, sulfur, and chlorine in
the soil at two landing sites suggest mixing in a large acidic
reservoir.^[16] Hematite deposits detected by TES have also been argued as
evidence of past liquid water.^[17]

Analysis of molecular hydrogen to deuterium ratios in the upper Mars
atmosphere from the NASA Far Ultraviolet Spectroscopic Explorer spacecraft
suggests an abundant water supply on primordial Mars.^[18]



[edit ] Fate of the ocean

Given the proposal of a vast primordial ocean on Mars, one may inquire as
to the fate of the water. As the Martian climate cooled, the surface of
the ocean would have frozen. One hypothesis states that part of the ocean
remains in a frozen state buried beneath a thin layer of rock, debris, and
dust on the flat northern plain Vastitus Borealis.^[19] The water could
have also been absorbed into the subsurface cryosphere^[1] or been lost to
the atmosphere (by sublimation) and eventually to space through
atmospheric sputtering^[12] .


[edit ] Alternate explanations

The existence of a primordial Martian ocean remains controversial among
scientists. The Mars Reconnaissance Orbiter's High Resolution Imaging
Science Experiment has discovered large boulders on the site of the
ancient seabed, which should contain only fine sediment.^[20] The
interpretations of some features as ancient shorelines has been
challenged.^[21]

Alternate theories for the creation of surface gullies and channels
include wind erosion^[22] , liquid carbon dioxide^[3] , and liquid
methane.^[17]


Confirmation or refutation of the Mars ocean hypothesis awaits additional
observational evidence from future Mars missions.


[edit ] See also

* Water on Mars * Extraterrestrial liquid water * Life on Mars


[edit ] References

1. ^ ^/*a*/ ^/*b*/ Clifford, S. M. and T. J. Parker, 2001: The Evolution
of the Martian Hydrosphere: Implications for the Fate of a Primordial
Ocean and the Current State of the Northern Plains , Icarus 154, 40-79. 2.
^ ^/*a*/ ^/*b*/ Baker, V. R., R. G. Strom, V. C. Gulick, J. S. Kargel, G.
Komatsu and V. S. Kale, 1991: Ancient oceans, ice sheets and the
hydrological cycle on Mars, Nature, 352, 589-594. 3. ^ ^/*a*/ ^/*b*/
^/*c*/ Read, Peter L. and S. R. Lewis, “The Martian Climate Revisited:
Atmosphere and Environment of a Desert Planet”, Praxis, Chichester, UK,
2004. 4. *^ * Zuber, Maria T., 2007: Planetary Science: Mars at the
tipping point, /Nature/, 447, 785-786. 5. *^ * Smith, D. et al. 1999.
Science: 284.1495 6. *^ * Boyce, J. M., P. Mouginis, and H. Garbeil, 2005:
"Ancient oceans in the northern lowlands of Mars: Evidence from impact
crater depth/diameter relationships", /Journal of Geophysical Research/,
110. 7. *^ *
http://www.astrobio.net/pressrelease/3322/martian-north-once-covered-by-ocean
8. *^ * http://www.space.com/scienceastronomy/091123-mars-ocean.html 9. ^
^/*a*/ ^/*b*/ Carr, Michael H., 1999: Retention of an atmosphere on early
Mars, /Journal of Geophysical Research/, 104, 21897-21909. 10. *^ *
Squyres, Steven W. and James F. Kasting, 1994: Early Mars: How warm and
how wet?, /Science/, 265, 744-749. 11. *^ * Forget, F. and R. T.
Pierrehumbert, 1997: Warming Early Mars with Carbon Dioxide Clouds That
Scatter Infrared Radiation, /Science/, 278, 1273-1276. 12. ^ ^/*a*/ ^/*b*/
Kass, D. M. and Y. L. Yung, 1995: Loss of atmosphere from Mars due to
solar wind-induced sputtering, /Science/, 268, 697-699. 13. *^ * Carr, M
and J. Head III. 2003. Oceans on Mars: An assessment of the observational
evidence and possible fate. Journal of Geophysical Research: 108. 5042.
14. *^ * Abe, Yutaka, Atsushi Numaguti, Goro Komatsu, and Yoshihide
Kobayashi, 2005: Four climate regimes on a land planet with wet surface:
Effects of obliquity change and implications for ancient Mars, /Icarus/,
Volume 178, Pages 27-39. 15. *^ * Fairen, A.G., D. Fernadez-Remolar, J. M.
Dohm, V.R. Baker, and R. Amils, 2004: Inhibition of carbonate synthesis in
acidic oceans on early Mars, /Nature/, 431, 423-426. 16. *^ * Greenwood,
James P. and Ruth E. Blake, 2006: Evidence for an acidic ocean on Mars
from phosphorus geochemistry of Martian soils and rocks, /Geology/, 34,
953-956. 17. ^ ^/*a*/ ^/*b*/ Tang, Y., Q. Chen and Y. Huang, 2006: Early
Mars may have had a methanol ocean, /Icarus/, 181, 88-92. 18. *^ *
Krasnopolsky, Vladimir A., and Paul D. Feldman, 2001: Detection of
Molecular Hydrogen in the Atmosphere of Mars, /Science/, 294, 1914-1917.
19. *^ * Janhunen, P., 2002: Are the northern plains of Mars a frozen
ocean?, /Journal of Geophysical Research/, 107, 5103. 20. *^ * Kerr,
Richard A., 2007: Is Mars Looking Drier and Drier for Longer and Longer?,
/Science/, 317, 1673. 21. *^ * Carr, M. H. and J.W. Head, 2002: Oceans on
Mars: An assessment of the observational evidence and possible fate,
/Journal of Geophysical Research/, 108. 22. *^ * Leovy, C.B., 1999: Wind
and climate on Mars, /Science/, 284, 1891a.