| China Geological Survey Chinese Academy of Geological Sciences | Host |
| 科学出版社 | Publish |
| Citation: |
DU Yun, GUO Aimin, LU Youyue, TIAN Lei, WANG Jingyuan, ZHOU Litong, FAN Hui, LUO Xiaoya. 2021. Petrogenesis of the Caledonian granites in the northern part of Miaoershan pluton, southwestern Hunan Province: Evidence from petrology, geochemistry and zircon U-Pb age[J]. Geology in China, 48(5): 1540-1561. doi: 10.12029/gc20210517
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Petrogenesis of the Caledonian granites in the northern part of Miaoershan pluton, southwestern Hunan Province: Evidence from petrology, geochemistry and zircon U-Pb age
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Abstract
The Miaoershan pluton, located at the junction of southwestern Hunan and Northern Guangxi, is a composite batholith composed of Jinningian, Caledonian, Indosinian and Yanshanian granites. Among them, Caledonian granites constitute the main body of the composite batholith, which can be divided into six intruding episodes. Through zircon LA-ICP-MS dating, the ages of the first, second and sixth episodic granites were measured at (428.1±3.6) Ma, (420.3±3.4)-(421.3±3.2) Ma and (408.3±3.5) Ma, respectively. The average (87Sr/86Sr)i, εNd(t) and the δ18O values of the Caledonian granites are 0.71765, -9.7, and 9.8, respectively. Caledonian granites are generally crust derived weak peraluminous-strong peraluminous granites, formed in post-collisional tectonic environment characterized by weakened compression and relaxed stress after the peak period of collision and extrusion. Their material and heat sources are different in the early and late stages. The early stage granites were derived from upper crustal metamorphic mudstone, psammite and/or metamorphic igneous rocks, and their formation temperature is relatively high(> 875℃). The late stage granites were derived from upper crustal metamorphic mudstone with lower formation temperature (< 875℃), showing the characteristics of typical S-type granites.
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DU Yun, GUO Aimin, LU Youyue, TIAN Lei, WANG Jingyuan, ZHOU Litong, FAN Hui, LUO Xiaoya. 2021. Petrogenesis of the Caledonian granites in the northern part of Miaoershan pluton, southwestern Hunan Province: Evidence from petrology, geochemistry and zircon U-Pb age[J]. Geology in China, 48(5): 1540-1561. doi: 10.12029/gc20210517
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Figure 1.
Tectonic location(a) and regional geological map(b)
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Figure 2.
Representative contacts between the different episodes of Caledonian granites
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Figure 3.
Representative photographs and photomicrographs of the first and third episodic granites and enclaves from the Miao'ershan pluton
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Figure 4.
Representative photographs and photomicrographs of the fifth and sixth episodic granites and enclaves from the Miao'ershan pluton
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Figure 5.
SiO2-(K2O+Na2O) diagram of the Caledonian granites
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Figure 6.
Geochemical classification diagram of the Caledonian granites
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Figure 7.
Primitive mantle-normalized trace elements spider diagram (a) and chondrite-normalized REE distribution panttern diagram (b) of the Caledonian granites
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Figure 8.
Cathodoluminescene(CL)images of representative zircons from Caledonian granites
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Figure 9.
U-Pb concordia diagram of zircons from the Caledonian granites
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Figure 10.
Rb/Sr-Rb/Ba diagram of the Caledonian granites (Symbols as Fig.5;after Sylvester,1998)
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Figure 11.
(87Sr/86Sr)i-εNd(t) and t-εNd(t) diagram for Caledonian granites (Symbols as Fig. 5, after Ling Hongfei, 2004)
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Figure 12.
Trace element tectonic environment discrimination diagram of the Caledonian granites (Symbols as Fig. 5, after Pearce et al., 1984)