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13 results on '"Interior Dynamics"'

1. Present‐Day Mars' Seismicity Predicted From 3‐D Thermal Evolution Models of Interior Dynamics.

Author

Plesa, A.‐C., Knapmeyer, M., Golombek, M. P., Breuer, D., Grott, M., Kawamura, T., Lognonné, P., Tosi, N., and Weber, R. C.

Abstract

Abstract: The Interior Exploration using Seismic Investigations, Geodesy and Heat Transport mission, to be launched in 2018, will perform a comprehensive geophysical investigation of Mars in situ. The Seismic Experiment for Interior Structure package aims to detect global and regional seismic events and in turn offer constraints on core size, crustal thickness, and core, mantle, and crustal composition. In this study, we estimate the present‐day amount and distribution of seismicity using 3‐D numerical thermal evolution models of Mars, taking into account contributions from convective stresses as well as from stresses associated with cooling and planetary contraction. Defining the seismogenic lithosphere by an isotherm and assuming two end‐member cases of 573 K and the 1073 K, we determine the seismogenic lithosphere thickness. Assuming a seismic efficiency between 0.025 and 1, this thickness is used to estimate the total annual seismic moment budget, and our models show values between 5.7 × 1016 and 3.9 × 1019 Nm. [ABSTRACT FROM AUTHOR]

Published
2018
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3. Interior dynamics and thermal evolution of Mars – a geodynamic perspective

Author

Plesa, Ana-Catalina, Wieczorek, Mark, Knapmeyer, Martin, Rivoldini, Attilio, Walterova, Michaela, and Breuer, Doris

Subjects
Earth and Planetary Astrophysics (astro-ph.EP), FOS: Physical sciences, Mars, Seismic velocities, Interior dynamics, Geodynamics, Astrophysics - Earth and Planetary Astrophysics, InSight, Thermal evolution
Abstract

Over the past decades, global geodynamical 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.

Published
2022
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8. Using InSight Data to Constrain Thermal Evolution Models

Author

Suzanne Smrekar, Sebastiano Padovan, Attilio Rivoldini, Mark A. Wieczorek, Doris Breuer, Ana-Catalina Plesa, William B. Banerdt, Matthew P. Golombek, Tilman Spohn, Matthias Grott, Nicola Tosi, Philippe Lognonné, and Martin Knapmeyer

Subjects
Thermal Evolution, Thermal, Interior Dynamics, Mars, Statistical physics, Geology, InSight
Published
2019

10. Present-day Mars' seismicity predicted from 3-D thermal evolution models of interior dynamics

Author

Matthias Grott, P. H. Lognonné, Ana-Catalina Plesa, Nicola Tosi, Matthew P. Golombek, Renee Weber, Taichi Kawamura, Doris Breuer, and Martin Knapmeyer

Subjects
010504 meteorology & atmospheric sciences, Dynamics (mechanics), interior dynamics, Mars, Geophysics, Mars Exploration Program, Present day, Induced seismicity, 01 natural sciences, 550 Geowissenschaften, 0103 physical sciences, Thermal, ddc:550, General Earth and Planetary Sciences, seismicity, thermal evolution, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences, InSight
Abstract

©2018. American Geophysical Union, The Interior Exploration using Seismic Investigations, Geodesy and Heat Transport mission, to be launched in 2018, will perform a comprehensive geophysical investigation of Mars in situ. The Seismic Experiment for Interior Structure package aims to detect global and regional seismic events and in turn offer constraints on core size, crustal thickness, and core, mantle, and crustal composition. In this study, we estimate the present‐day amount and distribution of seismicity using 3‐D numerical thermal evolution models of Mars, taking into account contributions from convective stresses as well as from stresses associated with cooling and planetary contraction. Defining the seismogenic lithosphere by an isotherm and assuming two end‐member cases of 573 K and the 1073 K, we determine the seismogenic lithosphere thickness. Assuming a seismic efficiency between 0.025 and 1, this thickness is used to estimate the total annual seismic moment budget, and our models show values between 5.7 × 1016 and 3.9 × 1019 Nm.

Published
2018

13. The Thermal State and Interior Structure of Mars.

Author

Plesa, A.‐C., Padovan, S., Tosi, N., Breuer, D., Grott, M., Wieczorek, M. A., Spohn, T., Smrekar, S. E., and Banerdt, W. B.

Subjects
*VOLCANIC ash, tuff, etc., *THERMAL analysis, *THERMAL conductivity, *MAGMAS, *CLIMATE change
Abstract

The present‐day thermal state, interior structure, composition, and rheology of Mars can be constrained by comparing the results of thermal history calculations with geophysical, petrological, and geological observations. Using the largest‐to‐date set of 3‐D thermal evolution models, we find that a limited set of models can satisfy all available constraints simultaneously. These models require a core radius strictly larger than 1,800 km, a crust with an average thickness between 48.8 and 87.1 km containing more than half of the planet's bulk abundance of heat producing elements, and a dry mantle rheology. A strong pressure dependence of the viscosity leads to the formation of prominent mantle plumes producing melt underneath Tharsis up to the present time. Heat flow and core size estimates derived from the InSight (Interior Exploration using Seismic Investigations, Geodesy and Heat Transport) mission will increase the set of constraining data and help to confine the range of admissible models. Plain Language Summary: We constrain the thermal state and interior structure of Mars by combining a large number of observations with thermal evolution models. Models that match the available observations require a core radius larger that half the planetary radius and a crust thicker than 48.8 km but thinner than 87.1 km on average. All best‐fit models suggest that more than half of the planet's bulk abundance of heat producing elements is located in the crust. Mantle plumes may still be active today in the interior of Mars and produce partial melt underneath the Tharsis volcanic province. Our results have important implications for the thermal evolution of Mars. Future data from the InSight (Interior Exploration using Seismic Investigations, Geodesy and Heat Transport) mission can be used to validate our models and further improve our understanding of the thermal evolution of Mars. Key Points: We combine the largest‐to‐date set of 3‐D dynamical models with observations to constrain the thermal state and interior structure of MarsBest‐fit models suggest a core radius strictly larger than 1,800 km and an average crustal thickness 48.8 km < dc < 87.1 kmModels suggest a large pressure dependence of the viscosity and a crust containing 65‐70% of the total amount of heat producing elements [ABSTRACT FROM AUTHOR]

Published
2018
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