Geochemistry and Tectonic Setting of the Eshan Granites in the Southwestern Margin of the Yangtze Plate, Yunnan

Jin Hu; Shitao Zhang; Guangzheng Zhang; Siyu Tao; Ying Zhang

doi:10.1007/s12583-017-0747-3

Journal of Earth Science ›› 2018, Vol. 29 ›› Issue (1) : 130 -143. DOI: 10.1007/s12583-017-0747-3

Mineralogy and Petrogeochemistry

Geochemistry and Tectonic Setting of the Eshan Granites in the Southwestern Margin of the Yangtze Plate, Yunnan

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Abstract

The extensive Eshan granites of Yunnan are made up of three intrusive units distinguished by their field contact relations; in descending order of age they are the Pojiao Unit, the Lüzicun Unit and the Mokela Unit. The Pojiao Unit and Lüzicun Unit contain petrographically and geochemically similar rocks but contact relationships show that the latter is younger. The Mokela Unit mainly consists of dykes intruding the other two and has petrographic and geochemical differences. Zircon U/Pb dating and zircon crystallization temperature measurements confirm the sequence of intrusions. Major and trace element analyses suggest that the magmas of the Pojiao Unit granites derived by partial melting of a clay-poor source from the upper crust; the magmas of the Lüzicun Unit granites derived by partial melting of upper crust with a small proportion of middle crust accompanied by crystallization of albite which triggered strength reduction. Both magmas mixed and underwent with crustal contamination, assimilation and fractional crystallization. The magmas of the Mokela Unit derived from residual melts and assimilation of argillaceous rocks. A time sequence of melting, intrusion and deformation events is derived from these results and compared with other published tectonic models for the evolution of the SW margin of the Yangtze Plate. Magmatism was initiated by exhumation of upper continental crust during which strongly peraluminous porphyritic biotite monzogranite granites were produced at ca. 854–852 Ma, and the genesis of two-mica granite reflected a later batch of exhumed melts with crustal contamination, assimilation and fractional crystallization at ca. 842 Ma. Finally biotite alkali-feldspar granite and tourmaline granite magmas experienced strong fractional crystallization, emplaced in the cooling stage at ca. 823 Ma, indicating the end of exhumation.

Keywords

Yangtze Plate / Eshan / granite / tectonic evolution / continental exhumation / postcollision

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Jin Hu, Shitao Zhang, Guangzheng Zhang, Siyu Tao, Ying Zhang. Geochemistry and Tectonic Setting of the Eshan Granites in the Southwestern Margin of the Yangtze Plate, Yunnan. Journal of Earth Science, 2018, 29(1): 130-143 DOI:10.1007/s12583-017-0747-3

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References

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[1]	Boehnke P., Watson E. B., Trail D., . Zircon Saturation Re-Revisited. Chemical Geology, 2013, 351: 324-334.

[2]	Chen Y. X., Song S. G., Niu Y. L., . Melting of Continental Crust during Subduction Initiation: A Case Study from the Chaidanuo Peraluminous Granite in the North Qilian Suture Zone. Geochimica et Cosmochimica Acta, 2014, 132: 311-336.

[3]	Deng H., Kusky T. M., Wang L., . Discovery of a Sheeted Dike Complex in the Northern Yangtze Craton and its Implications for Craton Evolution. Journal of Earth Science, 2012, 23(5): 676-695.

[4]	Du L. L., Guo J. H., Geng Y. S., . Age and Tectonic Setting of the Yanbian Group in the Southwestern Yangtze Block: Constraints from Clastic Sedimentary Rocks. Acta Petrologica Sinica, 2013, 29(2): 641-672.

[5]	Johannes W., Holtz F. Petrogenesis and Experimental Petrology of Granitic Rocks, 1996

[6]	Labrousse L., Prouteau G., Ganzhorn A. C. Continental Exhumation Triggered by Partial Melting at Ultrahigh Pressure. Geology, 2011, 39(12): 1171-1174.

[7]	Li X. H., Li W. X., He B. Building of the South China Block and Its Relevance to Assembly and Breakup of Rodinia Supercontinent: Observations, Interpretations and Tests. Bulletin of Mineralogy, Petrology and Geochemistry, 2012, 31(6): 543-559.

[8]	Li X. H., Li Z. X., Ge W. C., . Neoproterozoic Granitoids in South China: Crustal Melting above a Mantle Plume at ca. 825 Ma?. Precambrian Research, 2003, 122(1–4): 45-83.

[9]	Li Z. X., Bogdanova S. V., Collins A. S. Assembly, Configuration, and Break-Up History of Rodinia: A Synthesis Original Research Article. Precambrian Research, 2008, 160(1/2): 179-210.

[10]	Ling W. L., Gao S., Zhang B. R., . Neoproterozoic Tectonic Evolution of the Northwestern Yangtze Craton, South China: Implications for Amalgamation and Break-Up of the Rodinia Supercontinent. Precambrian Research, 2003, 122(1/2/3/4): 111-140.

[11]	Liu S. B. Zircon U-Pb Geochronology, Geochemistry and TectonicSetting of the Eshan Granite with Mo Mineralization inYunnan Province: [Dissertation], 2016.

[12]	Ma G. G. Isotopic Age of the Eshan Granite in Yunnan Province and Its Geological Significance. Bull. Yichang Inst. Geol. Miner. Res., 1991, 16: 121-129.

[13]	Patiño Douce A. E., Harris N. Experimental Constraints on Himalayan Anatexis. Journal of Petrology, 1998, 39(4): 689-710.

[14]	Petö P. An Experimental Investigation of Melting Relations Involving Muscovite and Paragonite in The Silica-Saturated Portion of The System K₂O-Na₂O-Al₂O₃-SiO₂-H₂O To 15 kb Total Pressure, 1976, Progress in Experimental Petrology.: NERC, London, 41-45.

[15]	Rudnick, R. L., Gao, S., 2014. Composition of the Continental Crust. In: Holland, H., Turekian, K., eds., Treatise on Geochemistry (Second Edition). Elsevier, [S.l.]. 1–64

[16]	Schmidt M. W., Poli S. Devolatilization during Subduction. Treatise Geochem., 2014, 4: 669-701.

[17]	Shen W. Z., Ling H. F., Xu S. J., . Geochemical Characteristics and Genesis of Some Neoproterozoic Granitoids in the Northern Part of the Western Margin of the Yangtze Block. Geological Review, 2000, 46(5): 512-519.

[18]	Song S. G., Wang M. J., Wang C., Niu Y. L. Magmatism during Continental Collision, Subduction, Exhumation and Mountain Collapse in Collisional Orogenic Belts and Continental Net Growth: A Perspective. Science China: Earth Sciences, 2015, 58: 1284-1304.

[19]	Stevens G., Clemens J. D., Droop G. T. R. Melt Production during Granulite-Facies Anatexis: Experimental Data from “Primitive” Metasedimentary Protoliths. Contributions to Mineralogy and Petrology, 1997, 128(4): 352-370.

[20]	Sun S. S., McDonough W. F. Chemical and Isotopic Systematics of Oceanic Basalts: Implications for Mantle Composition and Processes. Geological Society, London, Special Publications, 1989, 42(1): 313-345.

[21]	Sylvester P. J. Post-Collisional Strongly Peraluminous Granites. Lithos, 1998, 45(1/2/3/4): 29-44.

[22]	Wang J. Neoproterozoic Rifting History of South China: Significance to Rodinia Breakup: [Dissertation], 2000.

[23]	Wang X., Erdtmann B. D., Mao X. 30th IGC Field Trip Guide T106/T340: Geology of the Yangtze Gorges Area, 1996.

[24]	Watson E. B., Harrison T. M. Zircon Saturation Revisited: Temperature and Composition Effects in a Variety of Crustal Magma Types. Earth and Planetary Science Letters, 1983, 64(2): 295-304.

[25]	Weber M. B. I., Tarney J., Kempton P. D., . Crustal Make-Up of the Northern Andes: Evidence Based on Deep Crustal Xenolith Suites, Mercaderes, SW Colombia. Tectonophysics, 2002, 345(1/2/3/4): 49-82.

[26]	Wei C. J., Zhu W. P. Granulite Facies Metamorphism and Petrogenesis of Granite (I): Metamorphic Phase Equilibria for HT-UHT Metapelites/Greywackes. Acta Petrologica Sinica, 2016, 32(6): 1611-1624.

[27]	Wu F. Y., Liu Z. C., Liu X. C., . Himalayan Leucogranite: Petrogenesis and Implications to Orogenesis and Plateau Uplift. Acta Petrologica Sinica, 2015, 31(1): 1-36.

[28]	Xue X. H., Cai Z. B., Xiong J. Y. The Main Characteristics and Age Determination of E-Shan Granite in Yunnan Province. Acta Petrologica Sinica, 1986, 2(1): 50-58.

[29]	Zhang C. H., Gao L. Z., Wu Z. J. Tuff Zircon SHRIMP U-Pb Age of the Kunyang Group in Central Yunnan: Evidence of Greenwill Orogenic in Southern China. Chinese Science Bulletin, 2007, 52(7): 818-824.

[30]	Zhao Z. F., Zheng Y. F., Dai L. Q. Origin of Residual Zircon and the Nature of Magma Source for Postcollisional Granite in Continental Collision Zone. Chinese Science Bulletin, 2013, 58(23): 2285-2289.

[31]	Zheng Y. F., Yang J. H., Song S. G., . Progress in the Study of Chemical Geodynamics. Bulletin of Mineralogy, Petrology and Geochemistry, 2013, 32(1): 1-24.

[32]	Zheng Y. F., Zhang L.F., Liu L. Progress in the Study of Continental Deep Subduction and Ultrahigh Pressure Metamorphism. Bulletin of Mineralogy, Petrology and Geochemistry, 2013, 32(2): 135-158.

[33]	Zheng Y. F., Zhao Z. F., Chen Y. X. Continental Subduction Channel Processes: Plate Interface Interaction during Continental Collision. Chinese Science Bulletin, 2013, 58(35): 4371-4377.

[34]	Zheng Y. F., Zhang S. B., Zhao Z. F., . Contrasting Zircon Hf and O Isotopes in the Two Episodes of Neoproterozoic Granitoids in South China: Implications for Growth and Reworking of Continental Crust. Lithos, 2007, 96(1/2): 127-150.

[35]	Zhou J. C., Wang X. L., Qiu J. S. The Characters of Magmatism in the Western Section of the Jiangnan Orogenic Belt. Geological Journal of China Universities, 2005, 11(4): 527-533.

[36]	Zhou M. F., Yan D. P., Kennedy A. K., . SHRIMP^U-Pb Zircon Geochronological and Geochemical Evidence for Neoproterozoic Arc-Magmatism along the Western Margin of the Yangtze Block, South China. Earth and Planetary Science Letters, 2002, 196(1/2): 51-67.