The mechanical and thermal structure of Mercury's early lithosphere

Thomas R. Watters; Richard A. Schultz; Mark S. Robinson; Anthony C. Cook

doi:10.1029/2001GL014308

The mechanical and thermal structure of Mercury's early lithosphere

Thomas R. Watters, Richard A. Schultz, Mark S. Robinson, Anthony C. Cook

Research output: Contribution to journal › Article › peer-review

70 Scopus citations

Abstract

Insight into the mechanical and thermal structure of Mercury's early lithosphere has been obtained from forward modeling of the largest lobate scarp known on the planet. Our modeling indicates the structure overlies a thrust fault that extends deep into Mercury's lithosphere. The best-fitting fault parameters are a depth of faulting of 35 to 40 km, a fault dip of 30° to 35°, and a displacement of ∼2 km. The Discovery Rupes thrust fault probably cut the entire elastic and seismogenic lithosphere when it formed (∼4.0 Gyr ago). On Earth, the maximum depth of faulting is thermally controlled. Assuming the limiting isotherm for Mercury's crust is ∼300° to 600°C and it occured at a depth of ∼40 km, the corresponding heat flux at the time of faulting was ∼10 to 43 mW m^-2. This is less than old terrestrial oceanic lithosphere but greater than the present heat flux on the Moon.

Original language	English (US)
Pages (from-to)	37-1-37-4
Journal	Geophysical Research Letters
Volume	29
Issue number	11
DOIs	https://doi.org/10.1029/2001GL014308
State	Published - Jun 1 2002
Externally published	Yes

ASJC Scopus subject areas

Geophysics
General Earth and Planetary Sciences

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10.1029/2001GL014308

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abstract = "Insight into the mechanical and thermal structure of Mercury's early lithosphere has been obtained from forward modeling of the largest lobate scarp known on the planet. Our modeling indicates the structure overlies a thrust fault that extends deep into Mercury's lithosphere. The best-fitting fault parameters are a depth of faulting of 35 to 40 km, a fault dip of 30° to 35°, and a displacement of ∼2 km. The Discovery Rupes thrust fault probably cut the entire elastic and seismogenic lithosphere when it formed (∼4.0 Gyr ago). On Earth, the maximum depth of faulting is thermally controlled. Assuming the limiting isotherm for Mercury's crust is ∼300° to 600°C and it occured at a depth of ∼40 km, the corresponding heat flux at the time of faulting was ∼10 to 43 mW m-2. This is less than old terrestrial oceanic lithosphere but greater than the present heat flux on the Moon.",

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AU - Watters, Thomas R.

AU - Schultz, Richard A.

AU - Robinson, Mark S.

AU - Cook, Anthony C.

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The mechanical and thermal structure of Mercury's early lithosphere

Abstract

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