TY - JOUR
T1 - Timing and mechanisms of Tibetan Plateau uplift
AU - Ding, Lin
AU - Kapp, Paul
AU - Cai, Fulong
AU - Garzione, Carmala N.
AU - Xiong, Zhongyu
AU - Wang, Houqi
AU - Wang, Chao
N1 - Funding Information: This work was supported by the Second Tibetan Plateau Scientific Expedition and Research Program (Grant No. 2019QZKK0708), the National Natural Science Foundation of China BSCTPES project (Grant No. 41988101), the Chinese Academy of Sciences (XDA20070301) and the National Science Foundation of the United States (OISE-1545859 and EAR-2048656). The authors thank L. Bai, L. Zhang, H. Zhang and F. Ping for assistance with figure preparation. Publisher Copyright: © 2022, Springer Nature Limited.
PY - 2022/10
Y1 - 2022/10
N2 - The timing of the initial India–Asia collision and the mechanisms that led to the eventual formation of the high (>5 km) Tibetan Plateau remain enigmatic. In this Review, we describe the spatio-temporal distribution and geodynamic mechanisms of surface uplift in the Tibetan Plateau, based on geologic and palaeo-altimetric constraints. Localized mountain building was initiated during a Cretaceous microcontinent collision event in central Tibet and ocean–continent convergence in southern Tibet. Geological data indicate that India began colliding with Asian-affinity rocks 65–60 million years ago (Ma). High-elevation (>4 km) east–west mountain belts were established in southern and central Tibet by ~55 Ma and ~45 Ma, respectively. These mountain belts were separated by ≤2 km elevation basins centred on the microcontinent suture in central Tibet, until the basins were uplifted further between ~38 and 29 Ma. Basin uplift to ≥4 km elevation was delayed along the India–Asia suture zone until ~20 Ma, along with that in northern Tibet. Delamination and break-off of the subducted Indian and Asian lithosphere were the dominant mechanisms of surface uplift, with spatial variations controlled by inherited lithospheric heterogeneities. Future research should explore why surface uplift along suture zones — the loci of the initial collision — was substantially delayed compared with the time of initial collision.
AB - The timing of the initial India–Asia collision and the mechanisms that led to the eventual formation of the high (>5 km) Tibetan Plateau remain enigmatic. In this Review, we describe the spatio-temporal distribution and geodynamic mechanisms of surface uplift in the Tibetan Plateau, based on geologic and palaeo-altimetric constraints. Localized mountain building was initiated during a Cretaceous microcontinent collision event in central Tibet and ocean–continent convergence in southern Tibet. Geological data indicate that India began colliding with Asian-affinity rocks 65–60 million years ago (Ma). High-elevation (>4 km) east–west mountain belts were established in southern and central Tibet by ~55 Ma and ~45 Ma, respectively. These mountain belts were separated by ≤2 km elevation basins centred on the microcontinent suture in central Tibet, until the basins were uplifted further between ~38 and 29 Ma. Basin uplift to ≥4 km elevation was delayed along the India–Asia suture zone until ~20 Ma, along with that in northern Tibet. Delamination and break-off of the subducted Indian and Asian lithosphere were the dominant mechanisms of surface uplift, with spatial variations controlled by inherited lithospheric heterogeneities. Future research should explore why surface uplift along suture zones — the loci of the initial collision — was substantially delayed compared with the time of initial collision.
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U2 - 10.1038/s43017-022-00318-4
DO - 10.1038/s43017-022-00318-4
M3 - Review article
SN - 2662-138X
VL - 3
SP - 652
EP - 667
JO - Nature Reviews Earth and Environment
JF - Nature Reviews Earth and Environment
IS - 10
ER -