Crustal recycling, mantle dehydration, and the thermal evolution of Mars

Morschhauser, A.; Grott, M.; Breuer, D.

doi:10.1016/j.icarus.2010.12.028

Cited by 122 publications

(180 citation statements)

References 91 publications

(171 reference statements)

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“…5a, the thermal history is generally characterized by an initial heating phase during which convective cooling is not efficient enough to remove the internal heat generated by the decay of radioactive elements, a behaviour that is characteristic of the early evolution of the interior of stagnantlid bodies (e.g. Morschhauser et al 2011;Tosi et al 2013). After this phase, which lasts between 500 and 1500 Myr depending on the model parameters, the mantle and the core (not shown) cool at a roughly constant rate of ∼ 40 K/Gyr.…”

Section: Thermochemical Evolution Of the Interiormentioning

confidence: 99%

“…5c) stops growing when it becomes as thick as the stagnant lid; there is a sharp bend in the crust curves when they cross the stagnant-lid curves indicated with dashed lines. When this happens, the erosion of the bottom part of the crust starts (Morschhauser et al 2011) and continues until the rate at which the stagnant lid thickens because of mantle cooling overcomes the rate at which crust is produced. In our reference model, this phase lasts between ∼ 800 and 3300 Myr (thick black lines in Fig.…”

Section: Thermochemical Evolution Of the Interiormentioning

confidence: 99%

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The habitability of a stagnant-lid Earth

Tosi

Godolt

Stracke

et al. 2017

A&A

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126

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Context. Plate tectonics is considered a fundamental component for the habitability of the Earth. Yet whether it is a recurrent feature of terrestrial bodies orbiting other stars or unique to the Earth is unknown. The stagnant lid may rather be the most common tectonic expression on such bodies. Aims. To understand whether a stagnant-lid planet can be habitable, i.e. host liquid water at its surface, we model the thermal evolution of the mantle, volcanic outgassing of H 2 O and CO 2 , and resulting climate of an Earth-like planet lacking plate tectonics. Methods. We used a 1D model of parameterized convection to simulate the evolution of melt generation and the build-up of an atmosphere of H 2 O and CO 2 over 4.5 Gyr. We then employed a 1D radiative-convective atmosphere model to calculate the global mean atmospheric temperature and the boundaries of the habitable zone (HZ).Results. The evolution of the interior is characterized by the initial production of a large amount of partial melt accompanied by a rapid outgassing of H 2 O and CO 2 . The maximal partial pressure of H 2 O is limited to a few tens of bars by the high solubility of water in basaltic melts. The low solubility of CO 2 instead causes most of the carbon to be outgassed, with partial pressures that vary from 1 bar or less if reducing conditions are assumed for the mantle to 100-200 bar for oxidizing conditions. At 1 au, the obtained temperatures generally allow for liquid water on the surface nearly over the entire evolution. While the outer edge of the HZ is mostly influenced by the amount of outgassed CO 2 , the inner edge presents a more complex behaviour that is dependent on the partial pressures of both gases. Conclusions. At 1 au, the stagnant-lid planet considered would be regarded as habitable. The width of the HZ at the end of the evolution, albeit influenced by the amount of outgassed CO 2 , can vary in a non-monotonic way depending on the extent of the outgassed H 2 O reservoir. Our results suggest that stagnant-lid planets can be habitable over geological timescales and that joint modelling of interior evolution, volcanic outgassing, and accompanying climate is necessary to robustly characterize planetary habitability.

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Section: Thermochemical Evolution Of the Interiormentioning

confidence: 99%

Section: Thermochemical Evolution Of the Interiormentioning

confidence: 99%

The habitability of a stagnant-lid Earth

Tosi

Godolt

Stracke

et al. 2017

A&A

Self Cite

126

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“…This leaves us with two possible alternatives: a thick (>100 km) and non-porous basaltic crust, or a thin (∼50 km) stratified crust with a non-basaltic and/or porous component (Nimmo and Tanaka 2005;Baratoux et al 2014). The present-day average crustal thickness is poorly constrained by numerical simulations, with values ranging from several tens of kilometers to more than 100 km, depending on hypotheses made on the heat budget, water content, and mantle rheology (Hauck and Phillips 2002;Breuer and Spohn 2006;Fraeman and Korenaga 2010;Morschhauser et al 2011). A thick basaltic crust could also match with the moment of inertia factor (Baratoux et al 2014).…”

Section: Integrating Geophysical and Geochemical Approachesmentioning

confidence: 99%

“…Formation and early evolution of the crust likely involve significant degassing of the martian mantle (Jaskosky and Jones 1997; Filiberto et al 2016). In the absence of a mechanism for replenishment of the mantle in volatile species, it is usually considered that the present-day mantle is essentially dry, though even minor volatile concentration may have important consequences on the subsequent evolution (e.g., mantle rheology is sensitive to water levels at the level of ∼100 ppm, Morschhauser et al 2011) …”

Section: The Fate Of Volatilesmentioning

confidence: 99%

“…The volatile concentrations of the mantle source and the volume of magma reaching the surface (effusion rate) determine the amount of volatile species that have been released in the atmosphere as a function of time. In the absence of plate tectonics, the convecting mantle below the stagnant lid depletes continuously with time, as there is no mechanism to replenish the mantle with volatiles (Morschhauser et al 2011). Intense degassing likely took place during the formation and crystallization of the magma ocean.…”

Section: Implications Of the Interior Evolution To The Atmosphere Andmentioning

confidence: 99%

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Mars: a small terrestrial planet

Mangold

Baratoux

Witasse

et al. 2016

Astron Astrophys Rev

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Mars is characterized by geological landforms familiar to terrestrial geologists. It has a tenuous atmosphere that evolved differently from that of Earth and Venus and a differentiated inner structure. Our knowledge of the structure and evolution of Mars has strongly improved thanks to a huge amount of data of various types (visible and infrared imagery, altimetry, radar, chemistry, etc) acquired by a dozen of missions over the last two decades. In situ data have provided ground truth for remote-sensing data and have opened a new era in the study of Mars geology. While large sections of Mars science have made progress and new topics have emerged, a major question in Mars exploration-the possibility of past or present life-is still unsolved. Without entering into the debate around the presence of life traces, our review develops various topics of Mars science to help the search of life on Mars, building on the most recent discoveries, going from the exosphere to the interior structure, from the magmatic evolution to the currently active processes, including the fate of volatiles and especially liquid water.

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Dissipation at tidal and seismic frequencies in a melt‐free, anhydrous Mars

Nimmo

Faul

2013

JGR Planets

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[1] The measured inward motion of Phobos provides a constraint on the tidal dissipation factor, Q, within Mars. We model viscoelastic dissipation inside a convective Mars using a modified Burgers model based on laboratory experiments on anhydrous, melt-free olivine. The model tidal Q is highly sensitive to the mantle potential temperature and grain size assumed but relatively insensitive to the bulk density and rigidity structure. Q thus provides a tight constraint on the Martian interior temperature. By fitting the observed tidal Q and tidal Love number (k 2 ) values and requiring present-day melt generation, we estimate that for a grain size of 1 cm the current mantle potential temperature is 1625˙75 K, similar to that of the Earth. This estimate is consistent with recent petrologically derived determinations of mantle potential temperature but lower than estimates in some thermal evolution models. The presence of water in the Martian mantle would reduce our estimated temperature. Our preferred mantle grain size of 1 cm is somewhat larger than that of the Earth's upper mantle. The predicted mantle seismic Q is about 130 and is almost independent of depth. The Martian lithosphere represents a high seismic velocity lid, which should be readily detectable with future seismological observations. Citation: Nimmo, F., and U. H. Faul (2013), Dissipation at tidal and seismic frequencies in a melt-free, anhydrous Mars,

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Crustal recycling, mantle dehydration, and the thermal evolution of Mars

Cited by 122 publications

References 91 publications

The habitability of a stagnant-lid Earth

The habitability of a stagnant-lid Earth

Mars: a small terrestrial planet

Dissipation at tidal and seismic frequencies in a melt‐free, anhydrous Mars

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