Three-Dimensional Lithospheric Electrical Structure beneath the Handan-Xingtai District, North China: Implications for Tectonic Control of Skarn-Iron Mineralization

In this study, we determined the lithospheric electrical structure beneath the Handan-Xingtai district and its adjacent regions using magnetotelluric sounding data. To the west of the Handan-Xingtai district, the crust and upper mantle beneath the Taihang Mountains are mainly characterized by high r...

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Bibliographic Details
Published inMinerals (Basel) Vol. 13; no. 1; p. 14
Main Authors Zheng, Han, Yin, Yaotian, Jin, Sheng, Wei, Wenbo, Xu, Liuyang, Qi, Ping, Wang, Hongye, Wang, Qingyu
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.01.2023
Subjects
Asthenosphere
Conductivity
Convection
craton destruction
Dehydration
Electrical resistivity
Fault lines
Fluids
Geochemistry
Geology
Geophysical studies
Iron
Iron compounds
Lava
Lithosphere
lithospheric modification
Magma
magnetotelluric sounding
Mantle convection
Melts
Mesozoic
Mineralization
Mountains
Ocean circulation
Precambrian
Subduction
Subduction (geology)
Taihang Mountains
tectonic-magmatic factors of mineralization
Tectonics
Upper mantle
Upwelling
China
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Summary:In this study, we determined the lithospheric electrical structure beneath the Handan-Xingtai district and its adjacent regions using magnetotelluric sounding data. To the west of the Handan-Xingtai district, the crust and upper mantle beneath the Taihang Mountains are mainly characterized by high resistivity (>1000 Ωm, which we interpreted to be the relic cratonic lithosphere. In contrast, the lithosphere beneath the North China Plain to the east shows high-conductivity features (<100 Ωm) overall, which may indicate that it has suffered significant modifications. Additionally, other geological and geophysical studies suggested that this district was located in a significant boundary zone where the lithospheric thickness, temperature and geochemistry properties sharply changed. Combined with our resistivity model, we attributed this to the different degrees of lithospheric modification. Specifically, since the late Mesozoic, the subduction, roll-back and dehydration of the Pacific slab caused an unsteady asthenospheric flow and upwelling; therefore, the deep-derived melts and fluids concentrated within the uppermost mantle had even underplated or intruded into the crust, while this process had a negligible effect on the Taihang Mountains. Small-scale mantle convection and upwelling are likely to occur in this kind of transfer zone of lithospherice properties, leading to mantle-derived melts and fluids transporting upwardly near the surface, which was confirmed by the significantly enhanced conductivity beneath the ore district in our resistivity model. During this process, Fe derived from mantle-source magma or relic Precambrian metamorphic basement beneath the Taihang Mountains was extracted and emplaced along with the Yanshanian magmatism.
ISSN:2075-163X
2075-163X
DOI:10.3390/min13010014