TY - JOUR
T1 - Cretaceous long-distance lithospheric extension and surface response in South China
AU - Li, Jianhua
AU - Dong, Shuwen
AU - Cawood, Peter A.
AU - Thybo, Hans
AU - Clift, Peter D.
AU - Johnston, Stephen T.
AU - Zhao, Guochun
AU - Zhang, Yueqiao
N1 - Funding Information:
We thank Dr. Lianghui Guo and Rizheng He for providing the raw data in Figs. 7 a, b, 8 a, and 9 a. We thank the Editor, Prof. Gwenn Peron-Pinvidic, and two anonymous reviewers for their critical, careful, and constructive reviews that have greatly helped improve the manuscript. This work was financially supported by grants from the Natural Science Foundation of China ( 42072239 and 41822205 ), Basic Science Foundation of Institute of Geomechanics (No. JKYZD202319 ), Sino-Probe (08-01), Hong Kong RGC GRF ( 17307918 ), HKU Internal Grants for Member of Chinese Academy of Sciences ( 102009906 ) and Distinguished Research Achievement Award ( 102010100 ). Peter Cawood acknowledges support from the Australian Research Council grant FL160100168 . Stephen Johnston was supported by a National Science and Engineering Research Council grant ( RGPIN-2019-04275 ).
Publisher Copyright:
© 2023 Elsevier B.V.
PY - 2023/8
Y1 - 2023/8
N2 - Lithospheric extension plays a pivotal role in governing the evolution of continents and the birth of oceanic basins on Earth. Despite this, quantifying wide-mode lithospheric extension and its effects on surface uplift remain elusive. The vast (> 800-km-wide) Cretaceous extensional system in South China offers a unique opportunity to study the processes and mechanism(s) of wide-mode extension and their impacts. Here we review the essential constraints from crustal and mantle structures determined from geological, seismic reflection/refraction, and other geophysical data. Our compilation reveals a stratified lithosphere with depth-dependent extension in a magma-poor domain, expressed by normal faulting in the upper crust, ductile stretching in the mid-lower crust, and localized Moho uplift associated with mantle shear zones. From the magma-poor domain to the magma-rich domain, lateral variations in the extensional mode involve increased crustal melting, decreased crust-mantle decoupling, and mantle shear-zone abandonment caused by magmatic underplating. Extension-related strain fields across the South China lithosphere are uniformly NW-SE oriented, indicating vertically coherent deformation. Stress transmission across this coherent system likely occurred via basal traction and localized mantle shearing. Lower-crustal stretching and lithospheric removal accompanied and promoted the tectonic exhumation of extensional domes and mountain ranges. We propose a coupling between slab rollback, mantle flow, and lithospheric extension. Rollback-induced mantle flow likely drove lithospheric extension in South China by imposing shear forces at the lithosphere base.
AB - Lithospheric extension plays a pivotal role in governing the evolution of continents and the birth of oceanic basins on Earth. Despite this, quantifying wide-mode lithospheric extension and its effects on surface uplift remain elusive. The vast (> 800-km-wide) Cretaceous extensional system in South China offers a unique opportunity to study the processes and mechanism(s) of wide-mode extension and their impacts. Here we review the essential constraints from crustal and mantle structures determined from geological, seismic reflection/refraction, and other geophysical data. Our compilation reveals a stratified lithosphere with depth-dependent extension in a magma-poor domain, expressed by normal faulting in the upper crust, ductile stretching in the mid-lower crust, and localized Moho uplift associated with mantle shear zones. From the magma-poor domain to the magma-rich domain, lateral variations in the extensional mode involve increased crustal melting, decreased crust-mantle decoupling, and mantle shear-zone abandonment caused by magmatic underplating. Extension-related strain fields across the South China lithosphere are uniformly NW-SE oriented, indicating vertically coherent deformation. Stress transmission across this coherent system likely occurred via basal traction and localized mantle shearing. Lower-crustal stretching and lithospheric removal accompanied and promoted the tectonic exhumation of extensional domes and mountain ranges. We propose a coupling between slab rollback, mantle flow, and lithospheric extension. Rollback-induced mantle flow likely drove lithospheric extension in South China by imposing shear forces at the lithosphere base.
KW - Cretaceous
KW - Crustal and mantle processes
KW - Lithospheric extension
KW - South China
KW - Surface response
UR - http://www.scopus.com/inward/record.url?scp=85164678502&partnerID=8YFLogxK
U2 - 10.1016/j.earscirev.2023.104496
DO - 10.1016/j.earscirev.2023.104496
M3 - Review Article
AN - SCOPUS:85164678502
SN - 0012-8252
VL - 243
JO - Earth-Science Reviews
JF - Earth-Science Reviews
M1 - 104496
ER -