Your search keyword '"Wan-feng Zhang"' showing total 2 results

1. Timing and spatial variation of deformation along the Kanggur-Huangshan shear zone in the Chinese Tianshan: Implications for regional differential uplift and mineralization.

Author

Muhtar, M. N., Chang-Zhi Wu, Brzozowski, Matthew J., Santosh, M., Rong-Song Tian, Guo-Ai Xie, Wan-Feng Zhang, Ru-Xiong Lei, and Wen-Jiao Xiao

Subjects

*SHEAR zones, *SPATIAL variation, *OROGENIC belts, *DEFORMATIONS (Mechanics), *PROSPECTING, *SULFIDE ores, *ORE deposits, *METALLOGENY

Abstract

The Chinese Tianshan experienced large-scale transcurrent tectonics, synkinematic emplacement of ultramafic to felsic intrusions, and the formation of various mineral deposits during late Paleozoic accretionary orogenesis. The relationships among the spatial variation of deformation, the distribution of Permian orogenic Au and magmatic Ni-Cu sulfide deposits, and the kinematic evolution of crustal-scale shear zones, however, remain ambiguous. To address these ambiguities, the spatial variation in the degree of deformation in the Kanggur-Huangshan shear zone in the Chinese Tianshan was characterized using detailed structural measurements and zircon U-Pb and muscovite 40Ar/39Ar age data. The new structural data indicate that a prominent spatial variation exists in the style of deformation throughout the Kanggur-Huangshan shear zone; intense ductile deformation structures are dominant in the east, while brittle structures become progressively more dominant toward to the west. Zircon U-Pb and muscovite 40Ar/39Ar age data for syn- and Huangshan shear zone indicate that dextral strike-slip shearing occurred between 279 Ma and 249 Ma. The spatial variation in the degree of deformation and exhumation along the Kanggur-Huangshan shear zone was potentially caused by regional differential uplift induced by the collision of the Tianshan and Beishan regions; this was likely responsible for the predominant occurrence of magmatic Ni-Cu sulfide deposits in the eastern portion of the Kanggur-Huangshan shear zone and orogenic Au deposits in the western portion. The identified spatio-temporal relationship between deformation and distribution of orogenic Au and magmatic Ni-Cu sulfide deposits is crucial to the future success of mineral exploration in the Central Asian orogenic belt. [ABSTRACT FROM AUTHOR]

Published

2023

2. Pure sediment-derived granites in a subduction zone.

Author

Jian Xu, Xiao-Ping Xia, Qiang Wang, Spencer, Christopher J., Chun-Kit Lai, Jin-Long Ma, Le Zhang, Ze-Xian Cui, Wan-Feng Zhang, and Yan-Qiang Zhang

Subjects

*GRANITE, *SUBDUCTION zones, *OCEANIC crust, *ZONE melting, *GEOCHEMICAL modeling, *CONTINENTAL crust

Abstract

The Earth is unique in the Solar System due to significant volumes of granite in the lithosphere. However, the origins of granites are still highly debated, especially sedimentderived granites, which are often treated as a geochemical end-member of the continental crust. In the Yunnan region of South China, we identify the occurrence of pure sedimentderived granite in a subduction system. The suite of strongly peraluminous granite reported herein is interpreted to represent pure metasedimentary melts based on their wholerock elemental and Sr-Nd-B and zircon Hf-O isotopic compositions. These Late Permian-Early Triassic (ca. 254-248 Ma) granites are characterized by radiogenically enriched Sr, Nd, and Hf isotopic signatures. They show d11B and d18O signatures akin to those of continental shales. Geochemical modeling indicates no contributions from the mantle that can be detected. Considering the regional tectonic evolution, these granites are suggested to be formed in a subduction zone by decompression melting of rapidly exhumed backarc sediments. We posit that decompression melting was triggered by widespread extension and thinning of the crust prompted by rollback of the subducting oceanic crust. These granites thus provide evidence that granite formation in subduction zones does not necessarily contribute to crustal growth. These subduction-related pure sediment-derived granites have different elemental ratios and contents (e.g., Al2O3/TiO2 and Yb) from the Himalayan leucogranites. Considering their source compositions (e.g., pelitic rocks), which are similar to those of the Himalayan leucogranites, these differences are likely due to their higher formation temperature and lower pressure despite a great similarity in isotopic compositions. Identification of pure sediment-derived, strongly peraluminous granites (SPGs) in subduction systems provides an important geodynamic mechanism for crustal anatexis, which can both geochemically and tectonically complement their collisional counterparts identified in the Himalayas. [ABSTRACT FROM AUTHOR]

Published

2022