TY - JOUR
T1 - The Effects of Planetary and Stellar Parameters on Brittle Lithospheric Thickness
AU - Byrne, Paul K.
AU - Foley, Bradford J.
AU - Violay, Marie E.S.
AU - Heap, Michael J.
AU - Mikhail, Sami
N1 - Funding Information:
P. K. Byrne acknowledges support from North Carolina State University. Funding for S. Mikhail was provided by NERC standard grant NE/PO12167/1 and UK Space Agency Aurora grant ST/T001763/1. M. J. Heap thanks the Institut Universitaire de France (IUF) for support. The authors thank Jun Korenaga and Shintaro Azuma for constructive comments that improved this manuscript.
Funding Information:
P. K. Byrne acknowledges support from North Carolina State University. Funding for S. Mikhail was provided by NERC standard grant NE/PO12167/1 and UK Space Agency Aurora grant ST/T001763/1. M. J. Heap thanks the Institut Universitaire de France (IUF) for support. The authors thank Jun Korenaga and Shintaro Azuma for constructive comments that improved this manuscript.
Publisher Copyright:
© 2021. American Geophysical Union. All Rights Reserved.
PY - 2021/11
Y1 - 2021/11
N2 - The thickness of the brittle lithosphere—the outer portion of a planetary body that fails via fracturing—plays a key role in the geological processes of that body. The properties of both a planet and its host star can influence that thickness, and the potential range of those properties exceeds what we see in the Solar System. To understand how planetary and stellar parameters influence brittle lithospheric thickness generally, we modeled a comprehensive suite of combinations of planetary mass, surface and mantle temperature, heat flux, and strain rate. Surface temperature is the dominant factor governing the thickness of the brittle layer: smaller and older planets generally have thick brittle lithospheres, akin to those of Mercury and Mars, whereas larger, younger planets have thinner brittle lithospheres that may be comparable to the Venus lowlands. But certain combinations of these parameters yield worlds with exceedingly thin brittle layers. We predict that such bodies have little elevated topography and limited volatile cycling and weathering, which can be tested by future telescopic observations of known extrasolar planets.
AB - The thickness of the brittle lithosphere—the outer portion of a planetary body that fails via fracturing—plays a key role in the geological processes of that body. The properties of both a planet and its host star can influence that thickness, and the potential range of those properties exceeds what we see in the Solar System. To understand how planetary and stellar parameters influence brittle lithospheric thickness generally, we modeled a comprehensive suite of combinations of planetary mass, surface and mantle temperature, heat flux, and strain rate. Surface temperature is the dominant factor governing the thickness of the brittle layer: smaller and older planets generally have thick brittle lithospheres, akin to those of Mercury and Mars, whereas larger, younger planets have thinner brittle lithospheres that may be comparable to the Venus lowlands. But certain combinations of these parameters yield worlds with exceedingly thin brittle layers. We predict that such bodies have little elevated topography and limited volatile cycling and weathering, which can be tested by future telescopic observations of known extrasolar planets.
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U2 - 10.1029/2021JE006952
DO - 10.1029/2021JE006952
M3 - Article
AN - SCOPUS:85119840734
SN - 2169-9097
VL - 126
JO - Journal of Geophysical Research: Planets
JF - Journal of Geophysical Research: Planets
IS - 11
M1 - e2021JE006952
ER -