Origin of the martian dichotomy and Tharsis from a giant impact causing massive magmatism
Origin of the martian dichotomy and Tharsis from a giant impact causing massive magmatism
The origin of the ancient martian crustal dichotomy and the massive magmatic province of Tharsis remains an open problem. Here, we explore numerically a hypothesis for the origin of these two features involving both exogenic and endogenic processes. We propose a giant impact event during the late stage of planetary formation as the source of the southern highland crust. In a second stage, the extraction of excess heat by vigorous mantle convection on the impacted hemisphere leads to massive magmatism, forming a distinct Tharsis-like volcanic region. By coupling short-term and long-term numerical simulations, we are able to investigate both the early formation as well as the 4.5 Gyr evolution of the martian crust. We demonstrate numerically that this exogenic–endogenic hypothesis is in agreement with observational data from Mars.
346-357
Golabek, Gregor J.
39326924-b812-4005-b6d2-4fcd1b0a429c
Keller, Tobias
d8dfcfa5-89d1-4203-aa2d-8c142c00a169
Gerya, Taras V.
8afcb1d9-9da5-4600-9c31-c0fe02428b42
Zhu, Guizhi
b4598009-46f1-4893-996e-83803cdd9dfd
Tackley, Paul J.
9ed149f2-5d53-47a9-a9d9-e8609896c7e3
Connolly, James A.D.
90242ec0-504f-4e22-be64-9d210a9dd0d7
September 2011
Golabek, Gregor J.
39326924-b812-4005-b6d2-4fcd1b0a429c
Keller, Tobias
d8dfcfa5-89d1-4203-aa2d-8c142c00a169
Gerya, Taras V.
8afcb1d9-9da5-4600-9c31-c0fe02428b42
Zhu, Guizhi
b4598009-46f1-4893-996e-83803cdd9dfd
Tackley, Paul J.
9ed149f2-5d53-47a9-a9d9-e8609896c7e3
Connolly, James A.D.
90242ec0-504f-4e22-be64-9d210a9dd0d7
Golabek, Gregor J., Keller, Tobias and Gerya, Taras V.
,
et al.
(2011)
Origin of the martian dichotomy and Tharsis from a giant impact causing massive magmatism.
Icarus, 215 (1), .
(doi:10.1016/j.icarus.2011.06.012).
Abstract
The origin of the ancient martian crustal dichotomy and the massive magmatic province of Tharsis remains an open problem. Here, we explore numerically a hypothesis for the origin of these two features involving both exogenic and endogenic processes. We propose a giant impact event during the late stage of planetary formation as the source of the southern highland crust. In a second stage, the extraction of excess heat by vigorous mantle convection on the impacted hemisphere leads to massive magmatism, forming a distinct Tharsis-like volcanic region. By coupling short-term and long-term numerical simulations, we are able to investigate both the early formation as well as the 4.5 Gyr evolution of the martian crust. We demonstrate numerically that this exogenic–endogenic hypothesis is in agreement with observational data from Mars.
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Accepted/In Press date: 9 June 2011
e-pub ahead of print date: 22 June 2011
Published date: September 2011
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Local EPrints ID: 488390
URI: http://eprints.soton.ac.uk/id/eprint/488390
ISSN: 0019-1035
PURE UUID: 55e38a14-3cd4-4f99-8f30-e709fc4d5848
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Date deposited: 21 Mar 2024 17:37
Last modified: 22 Mar 2024 03:09
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Author:
Gregor J. Golabek
Author:
Tobias Keller
Author:
Taras V. Gerya
Author:
Guizhi Zhu
Author:
Paul J. Tackley
Author:
James A.D. Connolly
Corporate Author: et al.
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