Physics
Scientific paper
Dec 2001
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2001agufm.p31b..03b&link_type=abstract
American Geophysical Union, Fall Meeting 2001, abstract #P31B-03
Physics
5405 Atmospheres: Composition And Chemistry, 5407 Atmospheres: Evolution, 5480 Volcanism (8450), 8409 Atmospheric Effects (0370), 8450 Planetary Volcanism (5480)
Scientific paper
Two recent developments in the study of ancient Mars have led to new theoretical avenues for investigating the nature of its early climate. The first involves modeling of cloud processes and the greenhouse effect in the early martian atmosphere [Colaprete, 2000; Forget and Pierrehumbert, 1997; Mischna et al., 2000], and the second is an emerging view that the immense Tharsis province is an igneous construct that formed during the Noachian epoch [Phillips et al., 2001]. Whether the formation of infrared-scattering CO2 clouds could have warmed the surface sufficiently in a CO2-H2O atmosphere under a faint young sun to allow water to flow is unclear. As pointed out by Mischna et al. [2000], CO2 clouds in the ancient martian atmosphere may have had either a cooling or a warming effect, depending upon cloud location, altitudes, and optical depth. Colaprete [2000] found with a 1-D CO2 cloud model that as the atmosphere warms due to latent heating and radiative forcing by the clouds, the clouds dissipate, losing their radiative influence. Both investigations point to the necessity of 2 or 3-D cloud/climate models in order to address the net effect that clouds could have had on early Mars surface temperatures. The Phillips et al. [2001] picture of Tharsis, derived from MGS MOLA and gravity data, is that its emplacement must have been nearly complete while the largely Noachian valley networks were still forming. The volcanic magma from which Tharsis formed probably contained substantial quantities of water, CO2, and sulfur gases that would have been released, providing input of gases to the atmosphere and possibly contributing to an early, thicker atmosphere and cloud formation. This circumstantial connection provides some important constraints on climate and cloud models for Noachian Mars. We have begun a program to couple models of volatile outgassing due to the formation of Tharsis with atmospheric radiative-convective models that include parameterized cloud formation. We will discuss some results from 1 and 2-D models that bear on the effects that large injections of water, CO2 and sulfur gases may have had on cloud formation and surface temperatures of early Mars. Colaprete, A., Eos Trans. AGU, 81, 2000. Forget, F., and R.T. Pierrehumbert, Science, 278, 1273, 1997. Mischna, M.A., et al., Icarus, 145, 546, 2000. Phillips, R.J., et al., Science, 291, 2587, 2001.
Bullock Mark Alan
Grinspoon David H.
Phillips James R.
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