机构地区:[1]State Key Laboratory of Geological Processes and Mineral Resources, Faculty of Earth Sciences, China University of Geosciences [2]State Key Laboratory of Continental Dynamics, Northwest University
出 处:《Journal of Earth Science》2010年第5期669-691,共23页地球科学学刊(英文版)
基 金:study was co-supported by the National Natural Science Foundation of China (Nos. 90914007, 40821061, 90714010);the State Administration of Foreign Expert Affairs of China (No. B07039);the MOST Special Fund of State Key Laboratory of Geological Processes and Mineral Resources and State Key Laboratory of Continental Dynamics;the Special Fund For Basic Scientific Research of Central Colleges, China University of Geosciences (Wuhan)
摘 要:Garnet-rich granulite xenoliths collected from the Hannuoba basalts, the North China craton (NCC), were studied to reveal the Mesozoic crnst-mantle interaction. These xenoliths are characterized by low SiO2 (37.7 wt.%-46.0 wt.%) and high Al2O3 (10.8 wt.%-17.9 wt.%) contents. Their Mg# (60-75, Mg#=100×Mg/(Mg+Fe), atomic number) are relatively low for their low SiO2 contents. They have low rare-earth element (REE) contents and LREE-rich REE patterns, and show remarkable enrichments in Sr relative to the adjacent REE. Some of them exhibit convex RISE patterns with a maximum at Nd and remarkably positive Eu anomalies. Taking into account their high garnet mode (generally 〉30%), these features suggest that they are high-pressure metamorphic products of lowpressure cumulates (e.g., gabbro) after it had been depressed into the garnet stability field. They have evolved Nd and Sr isotopic compositions (143Nd/144Nd=0.511 763-0.512 173, STSr/86Sr=0.705 34-0.706 99) and fall in the trend defined by the 〉110 Ma Mesozoic basalts and high-Mg# andesites from the NCC. Zircon U-Pb dating by LA-ICP-MS shows a wide age range from 83 to 2 581 Ma, most of which cluster in 83-134 Ma. CL images of some Mesozoic zircons from the granulites show typical features of igneous zircons, providing direct evidence for the Mesozoic underplating event in this area. Neither peridotite-derived basaltic underplating model nor residue model of ancient lower crust after lithospheric thinning alone can reasonably explain the above features of the garnet-Hch granulite xenoliths. Combined with the previous research, we propose that most of the granulite xenoliths from the Hannuoba basalts are products of the Mesozoic magmatie underplating and mixing with the pre-existing lower crust (i.e., AFC process). However, the melts could be mostly derived from partial melting of basaltic layers that were previously subducted (a fossil oceanic slab) or underplated into the base of the lithospheric mantle, or from paGarnet-rich granulite xenoliths collected from the Hannuoba basalts, the North China craton (NCC), were studied to reveal the Mesozoic crnst-mantle interaction. These xenoliths are characterized by low SiO2 (37.7 wt.%-46.0 wt.%) and high Al2O3 (10.8 wt.%-17.9 wt.%) contents. Their Mg# (60-75, Mg#=100×Mg/(Mg+Fe), atomic number) are relatively low for their low SiO2 contents. They have low rare-earth element (REE) contents and LREE-rich REE patterns, and show remarkable enrichments in Sr relative to the adjacent REE. Some of them exhibit convex RISE patterns with a maximum at Nd and remarkably positive Eu anomalies. Taking into account their high garnet mode (generally 〉30%), these features suggest that they are high-pressure metamorphic products of lowpressure cumulates (e.g., gabbro) after it had been depressed into the garnet stability field. They have evolved Nd and Sr isotopic compositions (143Nd/144Nd=0.511 763-0.512 173, STSr/86Sr=0.705 34-0.706 99) and fall in the trend defined by the 〉110 Ma Mesozoic basalts and high-Mg# andesites from the NCC. Zircon U-Pb dating by LA-ICP-MS shows a wide age range from 83 to 2 581 Ma, most of which cluster in 83-134 Ma. CL images of some Mesozoic zircons from the granulites show typical features of igneous zircons, providing direct evidence for the Mesozoic underplating event in this area. Neither peridotite-derived basaltic underplating model nor residue model of ancient lower crust after lithospheric thinning alone can reasonably explain the above features of the garnet-Hch granulite xenoliths. Combined with the previous research, we propose that most of the granulite xenoliths from the Hannuoba basalts are products of the Mesozoic magmatie underplating and mixing with the pre-existing lower crust (i.e., AFC process). However, the melts could be mostly derived from partial melting of basaltic layers that were previously subducted (a fossil oceanic slab) or underplated into the base of the lithospheric mantle, or from pa
关 键 词:garnet-rich granulite xenolith trace element zircon U-Pb age Nd and Sr isotopes crust-mantle interaction North China craton.
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