塔里木板块东北部坡北基性–超基性岩体岩浆序列研究

doi:10.12677/AG.2018.87129

期刊菜单

塔里木板块东北部坡北基性–超基性岩体岩浆序列研究
Study on Magmatic Sequence of the Pobei Basic-Ultrabasic Complex in the Northeast Tarim Plate

DOI: 10.12677/AG.2018.87129, PDF,
作者: 王明卫：陕西省矿产资源调查评审指导中心，陕西西安；贾力, 陈炳龙：长安大学地球科学与资源学院，陕西西安；焦建刚：长安大学地球科学与资源学院，陕西西安；西部矿产资源与地质工程教育部重点实验室，陕西西安
关键词: 原生岩浆；岩浆过程；岩浆单元；岩浆子序列；坡北岩体；Primary Magma； Magma Process； Magma Unit； Magma Sub-Sequence； Pobei Complex

摘要: 坡北岩体位于新疆塔里木板块东北部，可划分为五个岩浆单元，对应五个岩相，分别为辉长岩相、辉长苏长岩相、橄榄辉长岩相、橄榄岩相和辉长岩岩枝。各单元岩石之间的矿物学特征存在差异，说明坡北岩体是不同期次岩浆侵入的产物。模拟计算获得橄榄岩相、橄榄辉长岩相和辉长苏长岩相岩石中橄榄石的平均结晶温度分别为：1303℃、1280℃和1204℃；橄榄岩相的原生岩浆的MgO含量为18%，属苦橄质岩浆；辉长岩相岩石原生岩浆MgO含量为8.61%，辉长苏长岩相岩石原生岩浆MgO含量为8.74%，均为玄武质岩浆。微量元素图解与Sr、Nd同位素指示岩浆演化过程中存在同化混染作用，辉长岩相和辉长苏长岩相受到的混染作用明显高于橄榄岩相和橄榄辉长岩相；辉长岩相、辉长苏长岩相和橄榄岩相的岩浆源区均为亏损岩石圈地幔，较低的部分熔融程度形成辉长岩相和辉长苏长岩相，较高的部分熔融程度形成橄榄岩相。

Abstract: The Pobei complex, located in the northeastern margin of the Tarim plate, can be divided into five magma units, corresponding to five lithofacies: gabbro facies, gabbronorite facies, olivine gabbro facies, peridotite facies and gabbro apophysis. The mineralogical characteristics of rocks from each unit are different, indicating that the Pobei complex is a product of different magma pulses. The average crystallization temperatures of olivine in peridotite facies, olivine gabbro facies and gabbronorite facies are 1303˚C, 1280˚C and 1204˚C, respectively. The MgO content of the primary magma of peridotite facies is 18%, suggesting a picritic magma. The MgO contents of the primary magma of gabbro facies and gabbronorite facies are 8.61% and 8.74%, respectively, all of which are basaltic magma. Trace element diagrams and Sr-Nd isotope indicate that contamination existed during the magmatic evolution process, and the degree of contamination in gabbro facies and gabbronorite facies is significantly higher than olivine gabbro facies and peridotite facies. The magma sources of gabbro facies, gabbronorites facies and peridotite facies are deplete lithosphere mantle, and the gabbro facies and gabbronorite facies are formed by lower degree of partial melting, while the peridotite facies is higher than them.

文章引用：王明卫, 贾力, 陈炳龙, 焦建刚. 塔里木板块东北部坡北基性–超基性岩体岩浆序列研究[J]. 地球科学前沿, 2018, 8(7): 1178-1194. https://doi.org/10.12677/AG.2018.87129

参考文献

[1]	姜常义, 程松林, 叶书锋, 等. 新疆北山地区中坡山北镁铁质岩体岩石地球化学与岩石成因[J]. 岩石学报, 2006, 22(1): 115-126.
[2]	姜常义, 郭娜欣, 夏明哲, 等. 塔里木板块东北部坡–镁铁质–超镁铁质层状侵入体岩石成因[J]. 岩石学报, 2012, 28(7): 2209-2223.
[3]	Xia, M.Z., Jiang, C.Y., Li, C.S. and Xia, Z.D. (2013) Characteristics of a Newly Discovered Ni-Cu Sulfide Deposit Hosted in the Poyi Ultramafic Intrusion, Tarim Craton, NW China. Economic Geology, 108, 1865-1878. [Google Scholar] [CrossRef]
[4]	Xue, S.C., Li, C.S., Qin, K.Z. and Tang, D.-M. (2016) A Non-Plume Model for the Permian Protracted (266 - 286 Ma) Basaltic Magmatism in the Beishan-Tianshan Region, Xinjiang, Western China. Lithos, 256, 243-249. [Google Scholar] [CrossRef]
[5]	郭娜欣. 塔里木板块东北部坡北岩体内镁铁质层状岩系岩石成因[D]: [硕士学位论文]. 长安: 长安大学, 2012.
[6]	郭娜欣, 姜常义, 宋艳芳, 等. 塔里木板块东北部坡北岩体内橄榄辉长苏长岩岩石成因[J]. 地质论评, 2012, 58(5): 873-886.
[7]	焦建刚, 芮会超, 夏明哲, 等. 基性–超基性侵入岩中-大比例尺专题地质填图实践——以塔里木板块东北部坡北岩体为例[J]. 地质通报, 2017, 36(11): 1999-2011.
[8]	Roeder, P.L. and Emslie, R.F. (1970) Olivine-Liquid Equilibrium. Earth and Environmental Science, 29, 275-289. [Google Scholar] [CrossRef]
[9]	Weaver, S. and Langmuir, C.H. (1990) Calculation of Phase Equilibrium in Mineral-Melt Systems. Computers & Geosciences, 16, 1-19. [Google Scholar] [CrossRef]
[10]	Le Bas, M.J. (1962) The Rock of Aluminium in Igneous Clinopyroxenes with Relation to Their Parentage. American Journal of Science, 260, 267-288. [Google Scholar] [CrossRef]
[11]	Kushiro, I. (1960) Si-Al Relation in Clinopyroxenes from Igneous Rocks. American Journal of Science, 258, 518-551. [Google Scholar] [CrossRef]
[12]	Sun, S.-S. and Mcdonough, W. (1989) Chemical and Isotopic Systematics of Oceanic Basalts: Implications for Mantle Composition and Processes. Geological Society, London, Special Publications, 42, 313-345. [Google Scholar] [CrossRef]
[13]	邓晋福. 岩石相平衡与岩石成因[M]. 武汉: 武汉地质学院出版社, 1987: 1-198.
[14]	Maier, W.D., Arndt, N.T. and Curl, E.A. (2000) Progressive Crustal Contamination of the Bushveld Complex: Evidence from Nd Isotopic Analtsis of the Cumulate Rocks. Contributions to Mineralogy and Petrology, 140, 316-327. [Google Scholar] [CrossRef]
[15]	Wood, D.A. (1980) The Application of a Th-Hf-Ta Diagram to Problems of Tectonomagmaric Classification and to Establishing the Nature of Crustal Contamination of Basaltic Lavas of the British Tertiary Volcanic Province. Earth and Planetary Science Letters, 50, 11-30. [Google Scholar] [CrossRef]
[16]	Marsh, J.S. (1989) Geochemical Constraints on Coupled Assimilation and Fractional Crystallization Involving Upper Crustal Compositions and Continental Tholeiitic Magma. Earth and Planetary Science Letters, 92, 70-80. [Google Scholar] [CrossRef]
[17]	Piccrillo, E.M., Civetta, L., Petrini, R., Longinelli, A., Bellieni, G., CominChiaramonti, P., Marques, L.S. and Melfi, A.J. (1989) Regional Variations within the Parana Flood Basalts (Southern Brazil): Evidence for Subcontinental Mantle Heterogeneity and Crustal Contamination. Chemical Geology, 75, 103-122. [Google Scholar] [CrossRef]
[18]	Barndon, A.D., HooPer, P.R., Goles, G.G. and Lamber, R.St.J. (1993) Evaluation Crustal Contamination in Continental Basalts: The Istopic Composition of the Picture Gorge Basalt of the Columbia River Basalt Group. Contributions to Mineralogy and Petrology, 225, 452-464. [Google Scholar] [CrossRef]
[19]	Preston, R.J. and Bell, B.R. (1997) Cognate Gabbroic Xenoliths from a Tholeiitic Subvolcanic Sill Complex: Implications for Fractional Crystallization and Crustal Contamination Processes. Mineralogical Magazine, 61, 329-349. [Google Scholar] [CrossRef]
[20]	Hansen, H. and Nielsen, T.F.D. (1999) Crustal Contamination in Palaeogene East Greenland Flood Basalts: Plumbing System Evolution during Continental Rifting. Chemical Geology, 157, 89-118. [Google Scholar] [CrossRef]
[21]	Stevenson, R.K., Henry, P. and Gariepy, C. (2009) Isotopic and Geochemical Evidence for Differentiation and Crustal Contamination from Granitoids of the Berens River Subprovince, Superior Province, Canada. Precanbrian Research, 168, 123-133. [Google Scholar] [CrossRef]
[22]	Qin, K., Su, B., Sakyi, P.A., et al. (2011) SIMS Zircon U-Pb Geochronology and Sr-Nd Isotopes of Ni-Cu-Bearing Mafic-Ultramafic Intrusions in Eastern Tianshan and Beishan in Correlation with Flood Basalts in Tarim Basin (NW China): Constraints on a ca. 280 Ma Mantle PLUME. American Journal of Science, 311, 237-260. [Google Scholar] [CrossRef]
[23]	Su, B.X., Qin, K.Z., Sakyi, P.A., Li, X.H., Yang, Y.H., Sun, H., Tang, D.M., Liu, P.P., Xiao, Q.H. and Malaviarachchi, S.P. (2011) U-Pb Ages and Hf-O Isotopes of Zircons from Late Paleozoic Mafic-Ultramafic Units in the Southern Central Asian Orogenic Belt: Tectonic Implications and Evidence for an Early-Permian Mantle Plume. Gondwana Research, 20, 516-531. [Google Scholar] [CrossRef]
[24]	Su, B.X., Qin, K.Z., Tang, D.M., Sakyi, P.A., Chu, Z.Y., Yang, Y.H., Sun, H., Liu, P.P., Xiao, Q.H. and Malaviarachchi, S.P. (2012) Subduction-Induced Mantle Heterogeneity beneath Eastern Tianshan and Beishan: Insights from Nd-Sr-Hf-O Isotopic Mapping of Late Paleozoic Mafic-Ultramafic Complexes. Lithos, 135, 41-51. [Google Scholar] [CrossRef]
[25]	Xue, S., Qin, K., Li, C., Tang, D., Mao, Y., Qi, L. and Ripley, E.M. (2016) Geochronological, Petrological, and Geochemical Constraints on Ni-Cu Sulfide Mineralization in the Poyi Ultramafic-Troctolitic Intrusion in the Northeast Rim of the Tarim Craton, Western China. Economic Geology, 111, 1465-1484. [Google Scholar] [CrossRef]

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