Asymmetric exhumation of the Mount Everest region: Implications for the tectono-topographic evolution of the Himalaya

B. Carrapa; X. Robert; P. G. DeCelles; D. A. Orme; S. N. Thomson; L. M. Schoenbohm

doi:10.1130/G37756.1

Asymmetric exhumation of the Mount Everest region: Implications for the tectono-topographic evolution of the Himalaya

B. Carrapa, X. Robert, P. G. DeCelles, D. A. Orme, S. N. Thomson, L. M. Schoenbohm

Geosciences

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27 Scopus citations

Abstract

The tectonic and topographic history of the Himalaya-Tibet orogenic system remains controversial, with several competing models that predict different exhumation histories. Here, we present new low-temperature thermochronological data from the Mount Everest region, which, combined with thermal-kinematic landscape evolution modeling, indicate asymmetric exhumation of Mount Everest consistent with a scenario in which the southern edge of the Tibetan Plateau was located >100 km farther south during the mid-Miocene. Northward plateau retreat was caused by erosional incision during the Pliocene. Our results suggest that the South Tibetan Detachment was a localized structure and that no coupling between precipitation and erosion is required for Miocene exhumation of Greater Himalayan Sequence rocks on Mount Everest.

Original language	English (US)
Pages (from-to)	611-614
Number of pages	4
Journal	Geology
Volume	44
Issue number	8
DOIs	https://doi.org/10.1130/G37756.1
State	Published - 2016

ASJC Scopus subject areas

Geology

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title = "Asymmetric exhumation of the Mount Everest region: Implications for the tectono-topographic evolution of the Himalaya",

abstract = "The tectonic and topographic history of the Himalaya-Tibet orogenic system remains controversial, with several competing models that predict different exhumation histories. Here, we present new low-temperature thermochronological data from the Mount Everest region, which, combined with thermal-kinematic landscape evolution modeling, indicate asymmetric exhumation of Mount Everest consistent with a scenario in which the southern edge of the Tibetan Plateau was located >100 km farther south during the mid-Miocene. Northward plateau retreat was caused by erosional incision during the Pliocene. Our results suggest that the South Tibetan Detachment was a localized structure and that no coupling between precipitation and erosion is required for Miocene exhumation of Greater Himalayan Sequence rocks on Mount Everest.",

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T1 - Asymmetric exhumation of the Mount Everest region

T2 - Implications for the tectono-topographic evolution of the Himalaya

AU - Carrapa, B.

AU - Robert, X.

AU - DeCelles, P. G.

AU - Orme, D. A.

AU - Thomson, S. N.

AU - Schoenbohm, L. M.

PY - 2016

Y1 - 2016

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AB - The tectonic and topographic history of the Himalaya-Tibet orogenic system remains controversial, with several competing models that predict different exhumation histories. Here, we present new low-temperature thermochronological data from the Mount Everest region, which, combined with thermal-kinematic landscape evolution modeling, indicate asymmetric exhumation of Mount Everest consistent with a scenario in which the southern edge of the Tibetan Plateau was located >100 km farther south during the mid-Miocene. Northward plateau retreat was caused by erosional incision during the Pliocene. Our results suggest that the South Tibetan Detachment was a localized structure and that no coupling between precipitation and erosion is required for Miocene exhumation of Greater Himalayan Sequence rocks on Mount Everest.

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Asymmetric exhumation of the Mount Everest region: Implications for the tectono-topographic evolution of the Himalaya

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