Effects of Crustal Eclogitization on Plate Subduction/Collision Dynamics: Implications for India-Asia Collision

2D thermo-mechanical models are constructed to investigate the effects of oceanic and continental crustal eclogitization on plate dynamics at three successive stages of oceanic subduction, slab breakoff, and continental subduction. Crustal eclogitization directly increases the average slab density a...

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Bibliographic Details
Published in:Journal of earth science (Wuhan, China) China), 2016-10, Vol.27 (5), p.727-739
Main Authors: Huangfu, Pengpeng, Wang, Yuejun, Li, Zhonghai, Fan, Weiming, Zhang, Yan
Format: Article
Language:English
Subjects:
Biogeosciences
Buoyancy
Collision dynamics
Continental crust
Crusts
Earth and Environmental Science
Earth science
Earth Sciences
Geochemistry
Geology
Geophysics
Geotechnical Engineering & Applied Earth Sciences
Heating
Lithosphere
Marine
Mathematical models
Metamorphism
Ocean models
Plate tectonics
Shear
Slabs
Upwelling
亚洲
印度
喜马拉雅造山带
大陆下地壳
大陆地壳
板块俯冲
热力模型
碰撞动力学
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Summary:2D thermo-mechanical models are constructed to investigate the effects of oceanic and continental crustal eclogitization on plate dynamics at three successive stages of oceanic subduction, slab breakoff, and continental subduction. Crustal eclogitization directly increases the average slab density and accordingly the slab pull force, which makes the slab subduct deeply and steeply. Numerical results demonstrate that the duration time from initial continental collision to slab breakoff largely depends on the slab pull force. Specifically, eclogitization of subducted crust can greatly decrease the duration time, but increase the breakoff depth. The detachment of oceanic slab from the pro-continental lithosphere is accompanied with obvious exhumation of the subducted continental crust and a sharp uplift of the collision zone in response to the disappearance of downward drag force and the induced asthenospheric upwelling, especially under the condition of no or incomplete crustal eclogitization. During continental subduction, the slab dip angle is strongly correlated with eclogitization of subducted continental lower crust, which regulates the slab buoyancy nature. Our model results can provide several important implications for the Himalayan-Tibetan collision zone. For example, it is possible that the lateral variations in the degree of eclogitization of the subducted Indian crust might to some extent contribute to the lateral variations of subduction angle along the Himalayan orogenic belt. Moreover, the accumulation of highly radiogenic sediments and upper continental crustal materials at the active margin in combination with the strong shear heating due to continuous continental subduction together cause rising of isotherms in the accretionary wedge, which facilitate the development of crustal partial melting and metamorphism.
ISSN:1674-487X
1867-111X
DOI:10.1007/s12583-016-0701-9