Hemispheric Dichotomy in Lithosphere Thickness on Mars Caused by Differences in Crustal Structure and Composition

Thiriet, Mélanie; Michaut, Chloé; Breuer, D.; Plesa, Ana‐Catalina

doi:10.1002/2017je005431

Cited by 27 publications

(61 citation statements)

References 120 publications

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“…All our best-fit models use a 62-km-thick crust with a uniform density of 3,100 kg/m 3 , in excellent agreement with petrological analyses of martian meteorites and surface rocks (Baratoux et al, 2014). A present-day crustal heat production rate of 44.1-49 pW/kg is in good agreement with the gamma-ray measurements (Hahn et al, 2011) and with a recent study (Thiriet et al, 2018), which employed parameterized thermal evolution models to investigate the thickness and enrichment of the southern and northern martian crusts. The present-day mantle would then contain only about 30-35% of the current bulk HPE inventory.…”

Section: Discussionmentioning

confidence: 61%

“…These studies assumed a uniform crustal thickness, while ours includes a suite of spatially varying crustal thickness models based on geophysical data. We find the interior of Mars to have a high reference viscosity representative of a dry mantle rheology, in agreement with other recent petrological and geodynamical studies Filiberto, Gross, et al, 2016;McCubbin et al, 2016;Thiriet et al, 2018). The thick crust covering the southern hemisphere together with a significant enrichment in HPE as suggested by gamma-ray spectroscopy data allows a thin elastic lithosphere during the Noachian even for a dry mantle.…”

Section: Discussionmentioning

confidence: 98%

“…Indeed, geological evidence suggests that the bulk of the crust has been built early during the planetary evolution (Greeley & Schneid, 1991;Nimmo & Tanaka, 2005). A present-day crustal heat production rate of 44.1-49 pW/kg is in good agreement with the gamma-ray measurements (Hahn et al, 2011) and with a recent study (Thiriet et al, 2018), which employed parameterized thermal evolution models to investigate the thickness and enrichment of the southern and northern martian crusts. A present-day crustal heat production rate of 44.1-49 pW/kg is in good agreement with the gamma-ray measurements (Hahn et al, 2011) and with a recent study (Thiriet et al, 2018), which employed parameterized thermal evolution models to investigate the thickness and enrichment of the southern and northern martian crusts.…”

Section: Discussionmentioning

confidence: 99%

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The Thermal State and Interior Structure of Mars

Plesa

Padovan

Tosi

et al. 2018

Geophysical Research Letters

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158

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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.

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Section: Discussionmentioning

confidence: 61%

Section: Discussionmentioning

confidence: 98%

Section: Discussionmentioning

confidence: 99%

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The Thermal State and Interior Structure of Mars

Plesa

Padovan

Tosi

et al. 2018

Geophysical Research Letters

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158

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“…Indeed, smaller values of ∼25 to 75 km, characteristics of hotter lithosphere and earlier times, are obtained by comparing tectonic observations and models of basin loading by lava infilling (McGovern & Litherland, 2011;Solomon & Head, 1979). Spatial differences in elastic thickness are also likely on the Moon, since heat producing elements appear concentrated in the Oceanus Procellarum Kreep Terrane, which might explain part of this discrepancy (Thiriet et al, 2018), though many FFCs are located close to this province. Spatial differences in elastic thickness are also likely on the Moon, since heat producing elements appear concentrated in the Oceanus Procellarum Kreep Terrane, which might explain part of this discrepancy (Thiriet et al, 2018), though many FFCs are located close to this province.…”

Section: Discussionmentioning

confidence: 99%

“…An elastic thickness of T e = 50 km is however inconsistent with FFC data since many FFCs would plot above the zero-pressure limit (Figures 3 and S3). Spatial differences in elastic thickness are also likely on the Moon, since heat producing elements appear concentrated in the Oceanus Procellarum Kreep Terrane, which might explain part of this discrepancy (Thiriet et al, 2018), though many FFCs are located close to this province.…”

Section: Discussionmentioning

confidence: 99%

Magma Ascent and Eruption Triggered by Cratering on the Moon

Michaut

Pinel

2018

Geophysical Research Letters

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On the Moon, the low‐density crust exerts a strong filter to magma ascent. Many lunar craters are filled with mare, and evidence of pyroclastic activity and shallow magmatism is often located within craters called floor‐fractured craters (FFCs). Interpreting quantitative observations on mare‐filled craters and FFCs based on mechanical models, we show that a surface unloading caused by an impact crater provides a driving overpressure to the magma stalling at depth. This overpressure counterbalances the melt negative buoyancy, favoring its ascent through the crust. Providing a large unloading and a thin crust, magma can ascend up to the crater floor. FFC characteristics are consistent with a magma denser than the crust by 200–300 kg/m3 and an elastic lithosphere thickness larger than 70 km. Our study suggests that small impact cratering likely induced magmatism and thereby crustal evolution in the early times of terrestrial planets.

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Pre-mission InSights on the Interior of Mars

et al. 2018

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The Interior exploration using Seismic Investigations, Geodesy, and Heat Transport (InSight) Mission will focus on Mars' interior structure and evolution. The basic structure of crust, mantle, and core form soon after accretion. Understanding the early differentiation process on Mars and how it relates to bulk composition is key to improving our understanding of this process on rocky bodies in our solar system, as well as in other solar B S.E. Smrekar

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Hemispheric Dichotomy in Lithosphere Thickness on Mars Caused by Differences in Crustal Structure and Composition

Cited by 27 publications

References 120 publications

The Thermal State and Interior Structure of Mars

The Thermal State and Interior Structure of Mars

Magma Ascent and Eruption Triggered by Cratering on the Moon

Pre-mission InSights on the Interior of Mars

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