| China Geological Survey Chinese Academy of Geological Sciences | Host |
| 科学出版社 | Publish |
| Citation: |
FU Jiangang, LI Guangming, WANG Genhou, HUANG Yong, ZHANG Linkui, DONG Suiliang, LIANG Wei. 2018. Establishment of the North Himalayan double gneiss domes: evidence from field identification of the Cuonadong dome, south Tibet[J]. Geology in China, 45(4): 783-802. doi: 10.12029/gc20180410
|
Establishment of the North Himalayan double gneiss domes: evidence from field identification of the Cuonadong dome, south Tibet
-
Abstract
The Cuonadong dome, which is firstly reported in this study, is exposed as an east-southern important part of the North Himalayan gneiss domes (NHGD), . The Cuonadong dome is located in the southern part of the Zhaxikang ore concentration area, which is divided into three tectono-lithostratigraphic units by two circle faults around the dome, which is geometrically from upper to lower (or from outer to inner) in order of cap rocks, decollement system and core, with the outer fault being upper detachment fault and the inner fault being lower detachment fault. The Cuonadong dome is a magmatic orthogneiss and leucogranite mantled by orthogneiss and metasedimentary rocks, which in turn are overlain by Jurassic metasedimentary and sedimentary rocks. The grades of metamorphism and structural deformation increase towards the core, which is consistent with the low to high degree metamorphic schist, tourmaline granitic biotite gneiss, garnet mica gneiss, and mylonitic quartz mica gneiss of the Ridang Formation. Their typical metamorphic minerals include garnet, staurolite, sillimanite and kyanite. The Cuonadong dome has preserved evidence for four major deformational events:southward thrust, early approximately N-S extensional deformation, main approximately E-W extensional deformation, and late collapse structural deformation around the core of the Cuonadong dome, which are consistent with four groups of lineation, respectively. The form of the Cuonadong dome resulted from the main E-W extension which resulted from eastward flow of middle or lower crust from beneath Tibet accommodated by northward oblique underthrusting of Indian crust beneath Tibet. The establishment of the Cuonadong dome has enhanced and enriched the significance of the E-W extension of the NHGD, which is further divided into two structural dome zones according to the different extensional directions:approximately NS extensional North Himalayan gneiss domes (NS-NHGD) and E-W extensional North Himalayan gneiss domes (EW-NHGD).
-
Keywords:
- dome /
- E-W extension /
- Cuonadong /
- Zhaxikang /
- North Himalayan gneiss domes (NHGD)
-
-
References
Aoya M, Wallis S R, Terada K, Lee J, Kawakami T, Wang Y, Heizler M. 2005. North-south extension in the Tibetan crust triggered by granite emplacement[J]. Geology, 33(11):853-856. doi: 10.1130/G21806.1 Armijo R., Tapponnier P, Mercier J L, Han T-L. 1986. Quaternary extension in southern Tibet:Field observations and tectonic implications[J].Journal of Geophysical Research:Solid Earth, 91(B14):13803-13872. doi: 10.1029/JB091iB14p13803 Blisniuk P M, Hacker B R, Glodny J, Ratschbacher L, Bi S, Wu Z, McWilliams M O, Calvert A. 2001. Normal faulting in central Tibet since at least 13.5 Myr ago[J].Nature, 412(6847):628-632. doi: 10.1038/35088045 Burg J P, and Chen G M. 1984. Tectonics and structural zonation of southern Tibet, China[J].Nature, 311(5983):219-223. doi: 10.1038/311219a0 Burg J P, Guiraud M, Chen G M, Li G C. 1984. Himalayan metamorphism and deformations in the North Himalayan Belt(southern Tibet, China)[J].Earth and Planetary Science Letters, 69(2):391-400. doi: 10.1016/0012-821X(84)90197-3 Chen Z, Liu Y, Hodges K V, Burchfiel B C, Royden L H, Deng C. 1990. The Kangmar Dome:A Metamorphic Core Complex in Southern Xizang (Tibet)[J].Science, 250(4987):1552-1556. doi: 10.1126/science.250.4987.1552 Cook K L, Royden L H. 2008. The role of crustal strength variations in shaping orogenic plateaus, with application to Tibet[J].Journal of Geophysical Research:Solid Earth, 113(B8):1-18. Copley A, McKenzie D. 2007. Models of crustal flow in the IndiaAsia collision zone[J].Geophysical Journal International, 169(2):683-698. doi: 10.1111/gji.2007.169.issue-2 DeCelles P G, Robinson D M, Zandt G. 2002. Implications of shortening in the Himalayan fold-thrust belt for uplift of the Tibetan Plateau[J].Tectonics, 21(6):1-12. Dewane T J, Stockli D F, Hager C, Taylor M, Ding L, Lee J, Wallis S. 2006. Timing of Cenozoic E-W Extension in the Tangra Yum CoKung Co Rift, south-central Tibet.Agu Fall Meeting Abstracts, 87:1-2. Ding H, Zhang Z, Dong X, Tian Z, Xiang H, Mu H, Gou Z, Shui X, Li W, Mao L. 2016. Early Eocene (ca. 50 Ma) collision of the Indian and Asian continents:Constraints from the North Himalayan metamorphic rocks, southeastern Tibet[J].Earth and Planetary Science Letters, 435:64-73. doi: 10.1016/j.epsl.2015.12.006 Edwards M, WSF K, Li J, Roden-Tice M, Copeland P. 1999. The Karo-La Décollement, southern Tibet:A Himalayan extensional structure domed by emplacement of the Late Miocene Karo-La Granite[J]. Geophys. Res., 99:40-45. England P, Houseman G. 1989. Extension during continental convergence, with application to the Tibetan Plateau[J].Journal of Geophysical Research:Solid Earth, 94(B12):17561-17579. doi: 10.1029/JB094iB12p17561 Gao Lie, Zeng Lingsen, Wang Li, Hou Kejun, Guo Chunli, Tang Suohan. 2013. Age and formation mechanism of the Malashan high-Ca two-mica granite within the Northern Himalayan Gneiss Domes, southern Tibet[J]. Acta Petrologica Sinica, 29(6):1995-2012(in Chinese with English abstract). Godin L, Brown R L, Hanmer S, Parrish R. 1999. Back folds in the core of the Himalayan orogen:An alternative interpretation[J]. Geology, 27(2):151-154. doi: 10.1130/0091-7613(1999)027<0151:BFITCO>2.3.CO;2 Guo Lei, Zhang Jinjiang, Zhang Bo. 2008. Structures, kinematics, thermochronology and tectonic evolution of the Ranba gneiss dome in the northern Himalaya[J]. Progress in Natural Science, 18(06):640-650(in Chinese). Harrison T M, Copeland P, Kidd W S F, Lovera O M. 1995. Activation of the Nyainqentanghla Shear Zone:Implications for uplift of the southern Tibetan Plateau[J].Tectonics, 14(3):658-676. doi: 10.1029/95TC00608 Harrison T M, Lovera O M, Grove M. 1997. New insights into the origin of two contrasting Himalayan granite belts[J].Geology, 25(10):899-902. doi: 10.1130/0091-7613(1997)025<0899:NIITOO>2.3.CO;2 Hou Zengqian, Pan Guitang, Wang Anjian, Mo Xuanxue, Tian Shihong, Sun Xiaoming, Ding Lin, Wang Erqi, Gao Yongfeng, Xie Yuling, Zeng Pusheng, Qin Kezhang, Xu Jifeng, Qu Xiaoming, Yang Zhiming, Yang Zhusen, Fei Hongcai, Meng Xiangjin, Li Zhenqing. 2006a. Metallogenesis in Tibetan collisional orogenic belt:Ⅱ.Minerallization in late-collisional transformation setting[J]. Mineral Deposits, 25(05):521-543(in Chinese with English abstract). Hou Zengqian, Qu Xiaoming, Yang Zhusen, Meng Xiangjin, Li Zhenqing, Yang Zhiming, Zheng Mianping, Zheng Youye, Nie Fengjun, Gao Yongfeng, Jiang Sihong, Li guangming. 2006b. Metallogenesis in Tibetan collisional orogenic belt: 2 Minerallization in post collisional extension setting[J]. Mineral Deposits, 25(06): 629-651 (in Chinese with English abstract). Jiménez-Munt I, Platt J P. 2006. Influence of mantle dynamics on the topographic evolution of the Tibetan Plateau:Results from numerical modeling[J].Tectonics, 25(6):1-17. Kawakami T, Aoya M, Wallis S, Lee J, Terada K, Wang Y, Heizler M. 2007. Contact metamorphism in the Malashan dome, North Himalayan gneiss domes, southern Tibet:an example of shallow extensional tectonics in the Tethys Himalaya[J].Journal of Metamorphic Geology, 25(8):831-853. doi: 10.1111/j.1525-1314.2007.00731.x King J, Harris N, Argles T, Parrish R, Zhang H. 2011. Contribution of crustal anatexis to the tectonic evolution of Indian crust beneath southern Tibet[J].Geological Society of America Bulletin, 123(1/2):218-239. Klootwijk C T, Conaghan P J, Powell C M. 1985. The Himalayan Arc:large-scale continental subduction, oroclinal bending and backarc spreading[J].Earth and Planetary Science Letters, 75(2/3):167-183. Langille J, Lee J, Hacker B, Seward G. 2010. Middle crustal ductile deformation patterns in southern Tibet:Insights from vorticity studies in Mabja Dome[J].Journal of Structural Geology, 32(1):70-85. doi: 10.1016/j.jsg.2009.08.009 Larson K P, Godin L, Davis W J, Davis D W. 2010. Out-of-sequence deformation and expansion of the Himalayan orogenic wedge:Insight from the Changgo culmination, south central Tibet[J]. Tectonics, 29(4):1-30. Le Fort P, Cuney M, Deniel C, France-Lanord C, Sheppard S, Upreti B, Vidal P. 1987. Crustal generation of the Himalayan leucogranites[J].Tectonophysics, 134(1):39-57. Lederer G, Cottle J, Jessup M, Langille J, Ahmad T. 2013. Timescales of partial melting in the Himalayan middle crust:insight from the Leo Pargil dome, northwest India[J].Contributions to Mineralogy and Petrology, 166(5):1415-1441. doi: 10.1007/s00410-013-0935-9 Lee J, Hacker B, Wang Y. 2004. Evolution of North Himalayan gneiss domes:structural and metamorphic studies in Mabja Dome, southern Tibet[J].Journal of Structural Geology, 26(12):2297-2316. doi: 10.1016/j.jsg.2004.02.013 Lee J, Hacker B R, Dinklage W S, Wang Y, Gans P, Calvert A, Wan J, Chen W, Blythe A E, McClelland W. 2000. Evolution of the Kangmar Dome, southern Tibet:Structural, petrologic, and thermochronologic constraints[J].Tectonics, 19(5):872-895. doi: 10.1029/1999TC001147 Lee J, Hager C, Wallis S R, Stockli D F, Whitehouse M J, Aoya M, Wang Y. 2011. Middle to late Miocene extremely rapid exhumation and thermal reequilibration in the Kung Co rift, southern Tibet[J]. Tectonics, 30(2):1-26. Lee J, McClelland W, Wang Y, Blythe A, McWilliams M. 2006. Oligocene-Miocene middle crustal flow in southern Tibet:geochronology of Mabja Dome.Geological Society, London, Special Publications, 268(1):445-469. doi: 10.1144/GSL.SP.2006.268.01.21 Lee J, Whitehouse M J. 2007. Onset of mid-crustal extensional flow in southern Tibet:Evidence from U/Pb zircon ages[J]. Geology, 35(1):45-48. doi: 10.1130/G22842A.1 Liang Wei, Yang Zhusen, Zheng Yuanchuan. 2015. The Zhaxikang PbZn deposit:Ar-Ar age of sericite and its metallogenic significance[J]. Acta Geologica Sinica, 89(3):560-568(in Chinese with English abstract). Liu M, Yang Y. 2003. Extensional collapse of the Tibetan Plateau:Results of three-dimensional finite element modeling[J].Journal of Geophysical Research:Solid Earth, 108(B8):1-15. Liu X C, Wu F Y, Yu L J, Liu Z C, Ji W Q, Wang J G. 2016a. Emplacement age of leucogranite in the Kampa Dome, southern Tibet[J].Tectonophysics, 667:163-175. doi: 10.1016/j.tecto.2015.12.001 Liu Z C, Wu F Y, Ding L, Liu X C, Wang J G, Ji W Q. 2016b. Highly fractionated Late Eocene (~35 Ma) leucogranite in the Xiaru Dome, Tethyan Himalaya, South Tibet[J]. Lithos, 240-243:337-354. Mahéo G, Leloup P H, Valli F, Lacassin R, Arnaud N, Paquette J L, Fernandez A, Haibing L, Farley K A, Tapponnier P. 2007. Post 4 Ma initiation of normal faulting in southern Tibet. Constraints from the Kung Co half graben[J]. Earth and Planetary Science Letters, 256(1/2):233-243. McCaffrey R, Nabelek J. 1998. Role of oblique convergence in the active deformation of the Himalayas and southern Tibet plateau[J]. Geology, 26(8):691-694. doi: 10.1130/0091-7613(1998)026<0691:ROOCIT>2.3.CO;2 McCallister A T, Taylor M H, Murphy M, Styron R H, Stockli D F. 2014. Thermochronologic constraints on the late Cenozoic exhumation history of the Gurla Mandhata metamorphic core complex, Southwestern Tibet[J].Tectonics, 33(2):27-52. doi: 10.1002/2013TC003302 Mercier J L, Armijo R, Tapponnier P, Carey-Gailhardis E, Lin H T. 1987. Change from Late Tertiary compression to Quaternary extension in southern Tibet during the India-Asia Collision[J]. Tectonics, 6(3):275-304. doi: 10.1029/TC006i003p00275 Mitsuishi M, Wallis S R, Aoya M, Lee J, Wang Y. 2012. E-W extension at 19 Ma in the Kung Co area, S. Tibet:Evidence for contemporaneous E-W and N-S extension in the Himalayan orogen[J]. Earth and Planetary Science Letters, 325-326(0):10-20. Molnar P, England P, Martinod J. 1993. Mantle dynamics, uplift of the Tibetan Plateau, and the Indian Monsoon[J].Reviews of Geophysics, 31(4):357-396. doi: 10.1029/93RG02030 Murphy M, Yin A, Kapp P, Harrison T, Manning C, Ryerson F, Lin D, Jinghui G. 2002. Structural evolution of the Gurla Mandhata detachment system, southwest Tibet:Implications for the eastward extent of the Karakoram fault system[J]. Geological Society of America Bulletin, 114(4):428-447. doi: 10.1130/0016-7606(2002)114<0428:SEOTGM>2.0.CO;2 Murphy M A. 2007. Isotopic characteristics of the Gurla Mandhata metamorphic core complex:Implications for the architecture of the Himalayan orogen[J]. Geology, 35(11):983-986. doi: 10.1130/G23774A.1 Quidelleur X, Grove M, Lovera O M, Harrison T M, Yin A, Ryerson F J. 1997. Thermal evolution and slip history of the Renbu Zedong Thrust, southeastern Tibet[J]. Journal of Geophysical Research:Solid Earth, 102(B2):2659-2679. doi: 10.1029/96JD02483 Quigley M, Liangjun Y, Xiaohan L, Wilson C J L, Sandiford M, Phillips D. 2006. 40Ar/39Ar thermochronology of the Kampa Dome, southern Tibet:Implications for tectonic evolution of the North Himalayan gneiss domes[J]. Tectonophysics, 421(3/4):269-297. Quigley M C, Liangjun Y, Gregory C, Corvino A, Sandiford M, Wilson C J L, Xiaohan L. 2008. U-Pb SHRIMP zircon geochronology and T-t-d history of the Kampa Dome, southern Tibet[J]. Tectonophysics, 446(1/4):97-113. Ratschbacher L, Frisch W, Liu G, Chen C. 1994. Distributed deformation in southern and western Tibet during and after the India-Asia collision[J]. Journal of Geophysical Research:Solid Earth, 99(B10):19917-19945. doi: 10.1029/94JB00932 Searle M P. 1999. Emplacement of Himalayan leucogranites by magma injection along giant sill complexes:examples from the Cho Oyu, Gyachung Kang and Everest leucogranites (Nepal Himalaya)[J]. Journal of Asian Earth Sciences, 17(5/6):773-783. Shen F, Royden L H, Burchfiel B C. 2001. Large-scale crustal deformation of the Tibetan Plateau[J].Journal of Geophysical Research:Solid Earth, 106(B4):6793-6816. doi: 10.1029/2000JB900389 Styron R H, Taylor M H, Murphy M A. 2011. Oblique convergence, arc-parallel extension, and the role of strike-slip faulting in the High Himalaya[J]. Geosphere, 7(2):582-596. doi: 10.1130/GES00606.1 Sun X, Zheng Y, Wang C, Zhao Z, Geng X. 2016. Identifying geochemical anomalies associated with Sb-Au-Pb-Zn-Ag mineralization in North Himalaya, southern Tibet[J]. Ore Geology Reviews, 73:1-12. doi: 10.1016/j.oregeorev.2015.10.020 Thiede R C, Arrowsmith J R, Bookhagen B, McWilliams M, Sobel E R, Strecker M R. 2006. Dome formation and extension in the Tethyan Himalaya, Leo Pargil, northwest India[J]. Geological Society of America Bulletin, 118(5/6):635-650. Wagner T, Lee J, Hacker B R, Seward G. 2010. Kinematics and vorticity in Kangmar Dome, southern Tibet:Testing midcrustal channel flow models for the Himalaya[J]. Tectonics, 29(6):1-26. Wang Genhou, Zhou Xiang, Zeng Qinggao, Pubu Ciren. 1997. Structure of the Kangmar therm-extensional metamorphic core complex, Xizang(Tibet)[J]. Journal of Chengdu University of Technology, 24(2):66-71(in Chinese with English abstract). Wang Xiaoxian, Zhang Jinjiang, Yan Shuyu, Liu Jiang. 2015. Structural characteristics and active time of the Kangmar detachment, Southern Tibet[J]. Geotectonica et Metallogenia, 39(2):250-259(in Chinese with English abstract). Wang Xiaoxian, Zhang Jinjiang, Yan Shuyu, Liu Jiang. 2016. Age and geochemistry of the Cuona leucogranite in southern Tibet and its geological implications[J]. Geological Bulletin of China, 35(1):91-103 (in Chinese with English abstract). Xu Zhiqin, Yang Jinsui, Li Wenchang, Zeng Lingsen, Xu Cuiping. 2012.Tectonic background of important metallogenic belts in the southern and southeastern Tibetan Plateau and ore prospecting[J]. Acta Geologica Sinica, 86(12):1857-1868 (in Chinese with English abstract). Xu Zhiqin, Wang Qin, Zeng Lingsen, Liang Fenghua, Li Huaqi, Qi Xuexiang, Cai Zhihui, Li Zhonghai, Cao Hui. 2013. Threedimensional extrusion model of the Great Himalaya slice[J]. Geology in China, 40(3):671-680(in Chinese with English abstract). Yin A. 2010. Cenozoic tectonic evolution of Asia:A preliminary synthesis[J].Tectonophysics, 488(1/4):293-325. Yin A. 2006. Cenozoic tectonic evolution of the Himalayan orogen as constrained by along-strike variation of structural geometry, exhumation history, and foreland sedimentation[J].Earth-Science Reviews, 76(1/2):1-131. Zeng L, Gao L, Xie K, Liu Z. 2011. Mid-Eocene high Sr/Y granites in the Northern Himalayan Gneiss Domes:Melting thickened lower continental crust[J].Earth and Planetary Science Letters, 303(3-4):251-266. doi: 10.1016/j.epsl.2011.01.005 Zhang Bo, Zhang Jinjiang, Guo Lei. 2006. Fractal analysis of dynamically recrystallized quartz grains and estimation of mainly rheological parameters of the Ranba ductile shear zone[J]. Chinese Journal of Geology, 41(1):158-169(in Chinese with English abstract). Zhang Hongfei, Harris N, Parrish R, Zhang Li, Zhao Zhidan, Li Dewei. 2005. Geochemistry of north Himalayan leucogranites:regional comparison, petrogenesis and tectonic implications[J]. Earth Science-Journal of China University of Geosciences, 30(3):275-288(in Chinese with English abstract). Zhang Jinjiang, Guo Lei, Zhang Bo. 2007. Structure and kinematics of the Yalashangbo dome in the northern Himalayan Dome belt, China[J]. Chinese Journal of Geology, 42(1):16-30(in Chinese with English abstract). Zhang Jinjiang, Yang Xiongying, Qi Guowei, Wang Dechao. 2011. Geochronology of the Malashan dome and its application in formation of the Southern Tibet detachment system(STDS) and Northern Himalayan gneiss domes(NHGD)[J]. Acta Petrologica Sinica, 27(12):3535-3544(in Chinese with English abstract). Zhang J, Ji J, Zhong D, Sang H, He S. 2002. Structural and Chronological Evidence for the India-Eurasia Collision of the Early Paleocene in the Eastern Himalayan Syntaxis, Namjagbarwa[J]. Acta Geologica Sinica-English Edition, 76(4):446-454. doi: 10.1111/j.1755-6724.2002.tb00098.x Zheng Youye, Sun Xiang, Tian Liming, Zheng Haitao, Yu Miao, Yang Wantao, Zhou Tiancheng, Geng Xuebin. 2014. Minerallization, deposit type and metallogenic age of the gold antimony polymetallic belt in the eastern part of North Himalayan[J]. Geotectonica et Metallogenia, 38(1):108-118(in Chinese with English abstract). 高利娥, 曾令森, 王莉, 侯可军, 郭春丽, 唐索寒. 2013.藏南马拉山高钙二云母花岗岩的年代学特征及其形成机制[J].岩石学报, 29(6):1995-2012. 郭磊, 张进江, 张波. 2008.北喜马拉雅然巴穹隆的构造、运动学特征、年代学及演化[J].自然科学进展, 18(6):640-650. 侯增谦, 潘桂棠, 王安建, 莫宣学, 田世洪, 孙晓明, 丁林, 王二七, 高永丰, 谢玉玲, 曾普胜, 秦克章, 许继峰, 曲晓明, 杨志明, 杨竹森, 费红彩, 孟祥金, 李振清. 2006a.青藏高原碰撞造山带:Ⅱ.晚碰撞转换成矿作用[J].矿床地质, 25(5):521-543. 侯增谦, 曲晓明, 杨竹森, 孟祥金, 李振清, 杨志明, 郑绵平, 郑有业, 聂凤军, 高永丰, 江思宏, 李光明. 2006b.青藏高原碰撞造山带:Ⅲ.后碰撞伸展成矿作用[J].矿床地质, 25(6):629-651. 梁维, 杨竹森, 郑远川. 2015.藏南扎西康铅锌多金属矿绢云母ArAr年龄及其成矿意义[J].地质学报, 89(3):560-568. 王根厚, 周详, 曾庆高, 普布次仁. 1997.西藏康马热伸展变质核杂岩构造研究[J].成都理工学院学报, 24(2):66-71. 王晓先, 张进江, 闫淑玉, 刘江. 2016.藏南错那淡色花岗岩LA-MC-ICP-MS锆石U-Pb年龄、岩石地球化学及其地质意义[J].地质通报, 35(1):91-103. 王晓先, 张进江, 闫淑玉, 刘江. 2015.藏南康马拆离断层的构造特征及其活动时代[J].大地构造与成矿学, 39(2):250-259. 许志琴, 王勤, 曾令森, 梁凤华, 李化启, 戚学祥, 蔡志慧, 李忠海, 曹汇. 2013.高喜马拉雅的三维挤出模式[J].中国地质, 40(3):671-680. 许志琴, 杨经绥, 李文昌, 曾令森, 许翠萍. 2012.青藏高原南部与东南部重要成矿带的大地构造定格与找矿前景[J].地质学报, 86(12):1857-1868. doi: 10.3969/j.issn.0001-5717.2012.12.001 张波, 张进江, 郭磊. 2006.北喜马拉雅穹隆带然巴韧性剪切带石英动态重结晶颗粒的分维几何分析与主要流变参数的估算[J].地质科学, 41(1):158-169. 张宏飞, Harris N, Parrish R, 张利, 赵志丹, 李德威. 2005.北喜马拉雅淡色花岗岩地球化学:区域对比、岩石成因及其构造意义[J].地球科学, 30(3):275-288. 张进江, 郭磊, 张波. 2007.北喜马拉雅穹隆带雅拉香波穹隆的构造组成和运动学特征[J].地质科学, 42(1):16-30. 张进江, 杨雄英, 戚国伟, 王德朝. 2011.马拉山穹隆的活动时限及其在藏南拆离系——北喜马拉雅片麻岩穹隆形成机制的应用[J].岩石学报, 27(12):3535-3544. 郑有业, 孙祥, 田立明, 郑海涛, 于淼, 杨万涛, 周天成, 耿学斌. 2014.北喜马拉雅东段金锑多金属成矿作用、矿床类型与成矿时代[J].大地构造与成矿学, 38(1):108-118. -
Access History
Figures(8)
Export File
Citation
FU Jiangang, LI Guangming, WANG Genhou, HUANG Yong, ZHANG Linkui, DONG Suiliang, LIANG Wei. 2018. Establishment of the North Himalayan double gneiss domes: evidence from field identification of the Cuonadong dome, south Tibet[J]. Geology in China, 45(4): 783-802. doi: 10.12029/gc20180410
Format
Content
DownLoad:
-
Figure 1.
Tectonic framework and deposits in northern Himalaya
-
Figure 2.
Regional tectonic map of the dome in the mid-eastern Himalaya
-
Figure 3.
Geological map of the Cuonadong dome and structural section crossing the Cuonadong dome
-
Figure 4.
Macroscopic petrology ranging from the outermost to the core of the dome (a-f) in the Cuonadong dome
-
Figure 5.
Microscopic petrology in the Cuonadong dome
-
Figure 7.
Field kinematics in the Cuonadong dome
-
Figure 6.
Typical lineations in the different parts of the Cuonadong dome
-
Figure 8.
Microscopic kinematics in the Cuonadong dome