InSight Constraints on the Global Character of the Martian Crust

Wieczorek, M. A.; Broquet, A.; McLennan, Scott M.; Rivoldini, Attilio; Golombek, M.; Antonangeli, Daniele; Beghein, Caroline; Giardini, Domenico; Гудкова, Т. В.; Gyalay, Szilard; Johnson, C. L.; Joshi, Rakshit; Kim, Doyeon; King, Scott D.; Knapmeyer‐Endrun, Brigitte; Lognonné, Philippe; Michaut, Chloé; Mittelholz, A.; Nimmo, F.; Ojha, L.; Panning, M. P.; Plesa, Ana‐Catalina; Siegler, M. A.; Smrekar, S. E.; Spohn, Tilman; Banerdt, B.

doi:10.1029/2022je007298

Cited by 57 publications

(139 citation statements)

References 165 publications

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“…The observed crustal thickness at the InSight landing site (Knapmeyer-Endrun et al, 2021) indicate two possible crustal thickness models: a two layer crust based on two strong seismic discontinuities or a three layer crust including a third weaker discontinuity recorded in the data. The extrapolation to global crustal thickness using gravity and topography data (Wieczorek and Zuber, 2004;Wieczorek et al, 2022) suggests an average crustal thickness between 24 and 72 km (Knapmeyer-Endrun et al, 2021), with the three layer crust showing values between 30 and 72 km (Wieczorek et al, 2022). We note that the range of crustal thicknesses of Wieczorek et al (2022) is larger than the range of 39 to 72 km presented in Knapmeyer-Endrun et al (2021).…”

Section: Geodynamic Modeling and Thermal Evolution Of Marsmentioning

confidence: 62%

“…Geodynamic models have been employed in previous studies to investigate the effects of crustal thickness variations, as derived from gravity and topography data, on the surface heat flow variations and the thermal state of the lithosphere (Plesa et al, 2016(Plesa et al, , 2018b. The crust in these studies does not change with time, but varies spatially according to the chosen crustal thickness model Wieczorek and Zuber (2004); Wieczorek et al (2022). Results show that the crustal thickness variations and the crustal enrichment in HPEs control the surface heat flow distribution at present day, the thickness of the lithosphere and the lithospheric temperature variations.…”

Section: Geodynamic Modeling and Thermal Evolution Of Marsmentioning

confidence: 99%

“…Crustal thickness models that can explain the gravity and topography data are non-unique. While an anchor point given by a crustal thickness value at a known location can help to constrain these models, one major assumption that remains is the density difference between mantle and crust (Wieczorek et al, 2022). Depending on the assumed crust-mantle density contrast, the difference between the crustal thickness of the southern and northern hemisphere can be small (Fig.…”

Section: Geodynamic Modeling and Thermal Evolution Of Marsmentioning

confidence: 99%

“…The extrapolation to global crustal thickness using gravity and topography data (Wieczorek and Zuber, 2004;Wieczorek et al, 2022) suggests an average crustal thickness between 24 and 72 km (Knapmeyer-Endrun et al, 2021), with the three layer crust showing values between 30 and 72 km (Wieczorek et al, 2022). We note that the range of crustal thicknesses of Wieczorek et al (2022) is larger than the range of 39 to 72 km presented in Knapmeyer-Endrun et al (2021). This is due to the fact that Wieczorek et al (2022) considered cases with a density dichotomy between the northern and southern hemisphere, while in Knapmeyer-Endrun et al (2021) only cases with a homogeneous crustal density were discussed.…”

Section: Geodynamic Modeling and Thermal Evolution Of Marsmentioning

confidence: 99%

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Interior Dynamics and Thermal Evolution of Mars -- a Geodynamic Perspective

Plesa¹,

Wieczorek²,

Knapmeyer³

et al. 2022

Preprint

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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. 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 presentday elastic lithosphere thickness at the north pole of Mars, the effects of lateral variations of seismic velocities on waves propagation through the mantle and lithosphere, and to test the spatial distribution of seismicity by comparing model predictions to observations.

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Section: Geodynamic Modeling and Thermal Evolution Of Marsmentioning

confidence: 62%

Section: Geodynamic Modeling and Thermal Evolution Of Marsmentioning

confidence: 99%

Section: Geodynamic Modeling and Thermal Evolution Of Marsmentioning

confidence: 99%

Section: Geodynamic Modeling and Thermal Evolution Of Marsmentioning

confidence: 99%

See 2 more Smart Citations

Interior Dynamics and Thermal Evolution of Mars -- a Geodynamic Perspective

Plesa¹,

Wieczorek²,

Knapmeyer³

et al. 2022

Preprint

Self Cite

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show abstract

“…Accordingly, the absence of a shallow layer characterized by low seismic wave speed (and thus low density) could be due to different processes depending on the precise location of the bounce point. If the bounce point is to the south of the dichotomy boundary, in areas underlain by Noachian crust, any largescale impact-induced porosity that might be expected in the upper crust would have to be reduced by processes such as viscous closure or thermal annealing during burial and/or occlusion of pore space by secondary minerals and/or ices (e.g., Wieczorek et al, 2022). On the other hand, if the bounce point is to the north of the dichotomy boundary or in an area resurfaced by Hesperian-Amazonian volcanism to the south, any pre-existing porosity in the uppermost crust may have been obscured or occluded by later, higher density magmatism (e.g., Wilson and Head, 1994).…”

Section: Discussionmentioning

confidence: 99%

Second Seismic Anchor Point of the Martian Crustal Structure Away From the InSight Landing Site

Beghein

McLennan

et al. 2022

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The most distant marsquake, S0976a, recorded so far by the InSight seismometer occurred at an epicentral distance of 146.3 ± 6.9o (Horleston et al., 2022), close to the western end of Valles Marineris. We have identified both SS and PP precursors, i.e., underside reflections off the crust-mantle (or intra-crustal) discontinuity between the marsquake and the instrument, on the seismograms, which directly constrain the crustal structure away (4000 km) from the InSight landing site. Inversion results show that the Martian crust at the bounce point between the lander and the event is characterized by an interface at 20 ± 5 km depth, similar to that seen beneath the InSight landing site (Knapmeyer-Endrun et al., 2021). However, a likely distinct feature at the bounce point compared to the lander site is the absence of a shallow layer (at 8 ± 2 km, with low seismic wave speed, Knapmeyer-Endrun et al., 2021), indicating that this layer is either local structure beneath the lander or related to the type of geologic unit or that has been obscured at the bounce point by later processes.

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Joint Inversion of receiver functions and apparent incidence angles to determine the crustal structure of Mars

Joshi

Knapmeyer‐Endrun²,

Mosegaard

et al. 2022

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Recent estimates of the crustal thickness of Mars show a bimodal result of either 20 km or 40 km beneath the InSight lander.We propose an approach based on random matrix theory applied to receiver functions to further constrain the subsurface structure. Assuming a spiked covariance model for our data, we first use the phase transition properties of the singular value spectrum of random matrices to detect coherent arrivals in the waveforms. Examples from terrestrial data show how the method works in different scenarios. We identify three new converted arrivals in the InSight data, including the second multiply reflected phase from a deeper third interface. We then use this information to jointly invert receiver functions with the absolute S-wave velocity information in the polarization of body waves. Results show a crustal thickness of 43±5 km beneath the lander with two mid-crustal interfaces at depths of 8.5±1.5 km and 22±3 km.

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InSight Constraints on the Global Character of the Martian Crust

Cited by 57 publications

References 165 publications

Interior Dynamics and Thermal Evolution of Mars -- a Geodynamic Perspective

Interior Dynamics and Thermal Evolution of Mars -- a Geodynamic Perspective

Second Seismic Anchor Point of the Martian Crustal Structure Away From the InSight Landing Site

Joint Inversion of receiver functions and apparent incidence angles to determine the crustal structure of Mars

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