机构地区:[1]Department of Physics,University of Alberta,Edmonton,Alberta T6G,2J1,Canada [2]School of Cosmic Physics,Dublin Institute of Advanced Studies,5 Merrion Square,Dublin 2,Ireland
出 处:《Science China Earth Sciences》2010年第2期189-202,共14页中国科学(地球科学英文版)
基 金:supported by National Natural Science Foundation of China (Grant No. 40674045);National Special Project of China Sino-Probe-01
摘 要:To understand deep lithosphere structure beneath the Qinghai-Tibet Plateau more comprehensively and objectively and to explore important scientific issues,such as characteristics of plateau lithospheric deformation,state of strain,thermal structure,plate (or terrane) movement,and crust-mantle rheology,it is necessary to research the variation of crust-mantle electrical structure in the east-west direction in every geological unit.For this purpose,six super-broadband magnetotelluric (MT) sounding profiles have been completed by INDEPTH-MT Project in the Himalayas-Southern Tibet.Based on the imaging results from the six profiles,three-dimensional electrical conductivity structure of the crust and upper mantle has been analyzed for the research area.The result shows that the high-conductivity layers in the middle and lower crust exist widely in Southern Tibet,which extend discontinuously for more than 1000 km in the east-west direction and become thinner,shallower and more resistive toward the big turning of the Yarlung Zangbo River.The discussion on the rheology of lithosphere in Southern Tibet suggests that the mid-lower crust there is of high electrical conductivity,implying the existence of "partial-melt" and "hot fluid" in the thick crust of Tibet,which make the medium hot,soft,and plastic,or even able to flow.Combining the experimental result of petrophysics and the MT data,we estimate the melting percentage of the crustal material to be up to 5%-14%,which would reduce the viscosity of aplite in the crust to meet the flow condition;but for granite,it is likely not enough to cause such a change in rheology.To understand deep lithosphere structure beneath the Qinghai-Tibet Plateau more comprehensively and objectively and to explore important scientific issues,such as characteristics of plateau lithospheric deformation,state of strain,thermal structure,plate (or terrane) movement,and crust-mantle rheology,it is necessary to research the variation of crust-mantle electrical structure in the east-west direction in every geological unit.For this purpose,six super-broadband magnetotelluric (MT) sounding profiles have been completed by INDEPTH-MT Project in the Himalayas-Southern Tibet.Based on the imaging results from the six profiles,three-dimensional electrical conductivity structure of the crust and upper mantle has been analyzed for the research area.The result shows that the high-conductivity layers in the middle and lower crust exist widely in Southern Tibet,which extend discontinuously for more than 1000 km in the east-west direction and become thinner,shallower and more resistive toward the big turning of the Yarlung Zangbo River.The discussion on the rheology of lithosphere in Southern Tibet suggests that the mid-lower crust there is of high electrical conductivity,implying the existence of 'partial-melt' and 'hot fluid' in the thick crust of Tibet,which make the medium hot,soft,and plastic,or even able to flow.Combining the experimental result of petrophysics and the MT data,we estimate the melting percentage of the crustal material to be up to 5%-14%,which would reduce the viscosity of aplite in the crust to meet the flow condition;but for granite,it is likely not enough to cause such a change in rheology.
关 键 词:Southern Tibet super-broadband MAGNETOTELLURIC sounding crust electrical CONDUCTIVITY rheological property
分 类 号:P542[天文地球—构造地质学] P631.325[天文地球—地质学]
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