Ancient Geodynamics and Global-Scale Hydrology on Mars

R. J. Phillips; M. T. Zuber; Sean C. Solomon; M. P. Golombek; B. M. Jakosky; W. B. Banerdt; David E. Smith; R. M. E. Williams; B. M. Hynek; O. Aharonson; S. A. Hauck

doi:10.1126/science.1058701

Ancient Geodynamics and Global-Scale Hydrology on Mars

R. J. Phillips, M. T. Zuber(Goddard Space Flight Center), Sean C. Solomon(Carnegie Institution for Science), M. P. Golombek(Jet Propulsion Laboratory), B. M. Jakosky(University of Colorado Boulder), W. B. Banerdt(Jet Propulsion Laboratory), David E. Smith(Goddard Space Flight Center), R. M. E. Williams, B. M. Hynek, O. Aharonson(Massachusetts Institute of Technology), S. A. Hauck

Science

March 30, 2001

10.1126/science.1058701

Cited by 495

Abstract

Loading of the lithosphere of Mars by the Tharsis rise explains much of the global shape and long-wavelength gravity field of the planet, including a ring of negative gravity anomalies and a topographic trough around Tharsis, as well as gravity anomaly and topographic highs centered in Arabia Terra and extending northward toward Utopia. The Tharsis-induced trough and antipodal high were largely in place by the end of the Noachian Epoch and exerted control on the location and orientation of valley networks. The release of carbon dioxide and water accompanying the emplacement of approximately 3 x 10(8) cubic kilometers of Tharsis magmas may have sustained a warmer climate than at present, enabling the formation of ancient valley networks and fluvial landscape denudation in and adjacent to the large-scale trough.

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