Interior dynamics and thermal evolution of Mars - a geodynamic perspective

Over the past decades, global geodynamic models have been used to investigate the thermal evolution of terrestrial planets. With the increase of computational power and improvement of numerical techniques, these models have become more complex, and simulations are now able to use a high resolution 3...

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Bibliographic Details
Main Authors: Plesa, Ana-Catalina, Wieczorek, Mark, Knapmeyer, Martin, Rivoldini, Attilio, Walterova, Michaela, Breuer, Doris
Format: Book Part
Language:unknown
Published: Elsevier 2022
Subjects:
Planetenphysik
North Pole
Online Access:https://elib.dlr.de/192213/
https://www.sciencedirect.com/science/article/abs/pii/S006526872200005X
id ftdlr:oai:elib.dlr.de:192213
record_format openpolar
spelling ftdlr:oai:elib.dlr.de:192213 2023-11-12T04:23:03+01:00 Interior dynamics and thermal evolution of Mars - a geodynamic perspective Plesa, Ana-Catalina Wieczorek, Mark Knapmeyer, Martin Rivoldini, Attilio Walterova, Michaela Breuer, Doris 2022-08-08 https://elib.dlr.de/192213/ https://www.sciencedirect.com/science/article/abs/pii/S006526872200005X unknown Elsevier Plesa, Ana-Catalina und Wieczorek, Mark und Knapmeyer, Martin und Rivoldini, Attilio und Walterova, Michaela und Breuer, Doris (2022) Interior dynamics and thermal evolution of Mars - a geodynamic perspective. In: Geophysical Exploration of the Solar System Advances in Geophysics, 63. Elsevier. Seiten 179-230. doi:10.1016/bs.agph.2022.07.005 <https://doi.org/10.1016/bs.agph.2022.07.005>. Planetenphysik Beitrag im Sammelband PeerReviewed 2022 ftdlr https://doi.org/10.1016/bs.agph.2022.07.005 2023-10-30T00:24:22Z Over the past decades, global geodynamic models have been used to investigate the thermal evolution of terrestrial planets. With the increase of computational power and improvement of numerical techniques, these models have become more complex, and simulations are now able to use a high resolution 3D spherical shell geometry and to account for strongly varying viscosity, as appropriate for mantle materials. In this study we review global 3D geodynamic models that have been used to study the thermal evolution and interior dynamics of Mars. We discuss how these models can be combined with local and global observations to constrain the planet's thermal history. In particular, we use the recent InSight estimates of the crustal thickness, upper mantle structure, and core size to show how these constraints can be combined with 3D geodynamic models to improve our understanding of the interior dynamics, present-day thermal state and temperature variations in the interior of Mars. Our results show that the crustal thickness variations control the surface heat flow and the elastic thickness pattern, as well as the location of melting zones in the present-day martian mantle. The lithospheric temperature and the seismic velocities pattern in the shallow mantle reflect the crustal thickness pattern. The large size of the martian core leads to a smaller scale convection pattern in the mantle than previously suggested. Strong mantle plumes that produce melt up to recent times become focused in Tharsis and Elysium, while weaker plumes are distributed throughout the mantle. The thickness of the seismogenic layer, where seismic events can occur, can be used to discriminate between geodynamic models, if the source depth and location of seismic events is known. Furthermore model predictions of present-day martian seismicity can be compared to the values measured by InSight. Future models need to consider recent estimates from the present-day elastic lithosphere thickness at the north pole of Mars, the effects of lateral variations ... Book Part North Pole German Aerospace Center: elib - DLR electronic library North Pole 179 230
institution Open Polar
collection German Aerospace Center: elib - DLR electronic library
op_collection_id ftdlr
language unknown
topic Planetenphysik
spellingShingle Planetenphysik
Plesa, Ana-Catalina
Wieczorek, Mark
Knapmeyer, Martin
Rivoldini, Attilio
Walterova, Michaela
Breuer, Doris
Interior dynamics and thermal evolution of Mars - a geodynamic perspective
topic_facet Planetenphysik
description Over the past decades, global geodynamic models have been used to investigate the thermal evolution of terrestrial planets. With the increase of computational power and improvement of numerical techniques, these models have become more complex, and simulations are now able to use a high resolution 3D spherical shell geometry and to account for strongly varying viscosity, as appropriate for mantle materials. In this study we review global 3D geodynamic models that have been used to study the thermal evolution and interior dynamics of Mars. We discuss how these models can be combined with local and global observations to constrain the planet's thermal history. In particular, we use the recent InSight estimates of the crustal thickness, upper mantle structure, and core size to show how these constraints can be combined with 3D geodynamic models to improve our understanding of the interior dynamics, present-day thermal state and temperature variations in the interior of Mars. Our results show that the crustal thickness variations control the surface heat flow and the elastic thickness pattern, as well as the location of melting zones in the present-day martian mantle. The lithospheric temperature and the seismic velocities pattern in the shallow mantle reflect the crustal thickness pattern. The large size of the martian core leads to a smaller scale convection pattern in the mantle than previously suggested. Strong mantle plumes that produce melt up to recent times become focused in Tharsis and Elysium, while weaker plumes are distributed throughout the mantle. The thickness of the seismogenic layer, where seismic events can occur, can be used to discriminate between geodynamic models, if the source depth and location of seismic events is known. Furthermore model predictions of present-day martian seismicity can be compared to the values measured by InSight. Future models need to consider recent estimates from the present-day elastic lithosphere thickness at the north pole of Mars, the effects of lateral variations ...
format Book Part
author Plesa, Ana-Catalina
Wieczorek, Mark
Knapmeyer, Martin
Rivoldini, Attilio
Walterova, Michaela
Breuer, Doris
author_facet Plesa, Ana-Catalina
Wieczorek, Mark
Knapmeyer, Martin
Rivoldini, Attilio
Walterova, Michaela
Breuer, Doris
author_sort Plesa, Ana-Catalina
title Interior dynamics and thermal evolution of Mars - a geodynamic perspective
title_short Interior dynamics and thermal evolution of Mars - a geodynamic perspective
title_full Interior dynamics and thermal evolution of Mars - a geodynamic perspective
title_fullStr Interior dynamics and thermal evolution of Mars - a geodynamic perspective
title_full_unstemmed Interior dynamics and thermal evolution of Mars - a geodynamic perspective
title_sort interior dynamics and thermal evolution of mars - a geodynamic perspective
publisher Elsevier
publishDate 2022
url https://elib.dlr.de/192213/
https://www.sciencedirect.com/science/article/abs/pii/S006526872200005X
geographic North Pole
geographic_facet North Pole
genre North Pole
genre_facet North Pole
op_relation Plesa, Ana-Catalina und Wieczorek, Mark und Knapmeyer, Martin und Rivoldini, Attilio und Walterova, Michaela und Breuer, Doris (2022) Interior dynamics and thermal evolution of Mars - a geodynamic perspective. In: Geophysical Exploration of the Solar System Advances in Geophysics, 63. Elsevier. Seiten 179-230. doi:10.1016/bs.agph.2022.07.005 <https://doi.org/10.1016/bs.agph.2022.07.005>.
op_doi https://doi.org/10.1016/bs.agph.2022.07.005
container_start_page 179
op_container_end_page 230
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