Solar system

Mars Climate Sounder: An investigation of thermal and water vapor structure, dust and condensate distributions in the atmosphere, and energy balance of the polar regions

JOURNAL OF GEOPHYSICAL RESEARCH-PLANETS 112:E5 (2007) ARTN E05S06

Authors:

DJ McCleese, JT Schofield, FW Taylor, SB Calcutt, MC Foote, DM Kass, CB Leovy, DA Paige, PL Read, RW Zurek

Simulating physical weathering of basalt on Earth and Mars

GEOCHIMICA ET COSMOCHIMICA ACTA 71:15 (2007) A1068-A1068

Authors:

Heather Viles, Bethany Ehlmann, Tomasz Cebula, Colin Wilson, Lisa Mol, Mary Bourke

New upper limits for hydrogen halides on Saturn derived from Cassini-CIRS data

Icarus 185 (2006) 466-475

Authors:

NA Teanby, Fletcher, LN, Irwin, PGJ, Fouchet, T

The dynamics behind Titan's methane clouds.

Proceedings of the National Academy of Sciences of the United States of America 103:49 (2006) 18421-18426

Authors:

Jonathan L Mitchell, Raymond T Pierrehumbert, Dargan MW Frierson, Rodrigo Caballero

Abstract:

We present results of an axisymmetric global circulation model of Titan with a simplified suite of atmospheric physics forced by seasonally varying insolation. The recent discovery of midlatitude tropospheric clouds on Titan has caused much excitement about the roles of surface sources of methane and the global circulation in forming clouds. Although localized surface sources, such as methane geysers or "cryovolcanoes," have been invoked to explain these clouds, we find in this work that clouds appear in regions of convergence by the mean meridional circulation and over the poles during solstices, where the solar forcing reaches its seasonal maximum. Other regions are inhibited from forming clouds because of dynamical transports of methane and strong subsidence. We find that for a variety of moist regimes, i.e., with the effect of methane thermodynamics included, the observed cloud features can be explained by the large-scale dynamics of the atmosphere. Clouds at the solsticial pole are found to be a robust feature of Titan's dynamics, whereas isolated midlatitude clouds are present exclusively in a variety of moist dynamical regimes. In all cases, even without including methane thermodynamics, our model ceases to produce polar clouds approximately 4-6 terrestrial years after solstices.

A GEOCLIM simulation of climatic and biogeochemical consequences of Pangea breakup

Geochemistry Geophysics Geosystems American Geophysical Union (AGU) 7:11 (2006)

Authors:

Y Donnadieu, Y Goddéris, R Pierrehumbert, G Dromart, F Fluteau, R Jacob