地质学
岩石圈
均衡
地幔对流
山脉形成
构造学
构造隆升
古生物学
海洋表面地形
地幔(地质学)
高原(数学)
地温梯度
地球科学
气候学
数学
数学分析
作者
Alireza Bahadori,W. E. Holt,Ran Feng,Jacqueline Austermann,Katharine M. Loughney,Tristan Salles,Louis Moresi,Romain Beucher,Neng Lu,L. M. Flesch,Christopher M. Calvelage,E. Troy Rasbury,Daniel M. Davis,Andre R. Potochnik,W. Bruce Ward,Kevin W. Hatton,Saad S.B. Haq,Tara M. Smiley,Kathleen Wooton,Catherine Badgley
标识
DOI:10.1038/s41467-022-31903-2
摘要
The Cenozoic landscape evolution in southwestern North America is ascribed to crustal isostasy, dynamic topography, or lithosphere tectonics, but their relative contributions remain controversial. Here we reconstruct landscape history since the late Eocene by investigating the interplay between mantle convection, lithosphere dynamics, climate, and surface processes using fully coupled four-dimensional numerical models. Our quantified depth-dependent strain rate and stress history within the lithosphere, under the influence of gravitational collapse and sub-lithospheric mantle flow, show that high gravitational potential energy of a mountain chain relative to a lower Colorado Plateau can explain extension directions and stress magnitudes in the belt of metamorphic core complexes during topographic collapse. Profound lithospheric weakening through heating and partial melting, following slab rollback, promoted this extensional collapse. Landscape evolution guided northeast drainage onto the Colorado Plateau during the late Eocene-late Oligocene, south-southwest drainage reversal during the late Oligocene-middle Miocene, and southwest drainage following the late Miocene.
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