OALib Journal期刊
ISSN: 2333-9721
费用：99美元

投递稿件

查看量	下载量

相关文章
更多...

中国科学地球科学中国科学地球科学 2015

桐柏-红安造山带的构造演化:从大洋俯冲/增生到陆陆碰撞

, PP. 1088-1108

刘晓春,李三忠,江博明

Keywords: 大洋俯冲,增生,大陆俯冲,碰撞,桐柏-红安造山带

Full-Text Cite this paper Add to My Lib

Abstract:

？桐柏-红安造山带位于秦岭与大别-苏鲁造山带之间,因其完好地保存了古生代增生造山体系和古生代末-中生代碰撞造山体系而成为了解华北-华南陆块之间构造演化的关键地区.近20年来的可利用研究资料表明,桐柏-红安造山带显生宙的总体构造演化框架包括以下4个主要阶段:(1)早古生代(490~420Ma)大洋俯冲、岛弧增生与弧陆碰撞,从而于早古生代末在华北陆块南缘形成一个新的安第斯型大陆边缘;(2)晚古生代(340~310Ma)大洋俯冲与增生,进而在商丹-松扒断裂南侧形成变质时代相同,但变质作用类型不同的“双变质带”,即被分割的武关-龟山中级变质杂岩带和熊店高压榴辉岩带;(3)晚古生代末-早中生代(255~200Ma)大陆俯冲与陆陆碰撞,通过华南大陆岩板东深西浅的俯冲和多层次拆离/折返形成桐柏高压变质地体和红安高压/超高压变质地体;(4)晚中生代(140~120Ma)伸展、大规模岩浆侵位与构造挤出,造成桐柏-红安-大别高压/超高压变质地体最终出露地表及东宽西窄的构造格局.然而,对每一构造演化阶段的具体细节以及早期地质历史的认识方面还存在着诸多争议和(或)难以解释的问题.未来的研究除在桐柏-红安造山带继续开展深入细致的工作外,还需与西部“软碰撞”的秦岭造山带和东部“硬碰撞”的大别-苏鲁造山带的研究紧密结合,以期建立适合于整个秦岭-桐柏-红安-大别-苏鲁造山带从古生代到中生代的经典构造演化模型.

References

[1]	Wang H, Wu Y B, Qin Z W, Zhu L Q, Liu Q, Liu X C, Gao S, Wijbrans J R, Zhou L, Gong H J, Yuan H L. 2013a. Age and geochemistry of Silurian gabbroic rocks in the Tongbai orogen, central China: Implications for the geodynamic evolution of the North Qinling arc-back-arc system. Lithos, 179: 1-15
[2]	Wang H, Wu Y B, Gao S, Liu X C, Liu Q, Qin Z W, Xie S W, Zhou L, Yang S H. 2013b. Continental origin of eclogites in the North Qinling terrane and its tectonic implications. Precambrian Res, 230: 13-30
[3]	Webb L E, Hacker B R, Ratschbacher L, Dong S W. 1999. Thermochronologic constraints on deformation and cooling history of high- and ultrahigh-pressure rocks in the Qinling-Dabie orogen, eastern China. Tectonics, 18: 621-638
[4]	Webb L E, Ratschbacher L, Hacker B R, Dong S W. 2001. Kinematics of exhumation of high- and ultrahigh-pressure rocks in the Hong’an and Tongbai Shan of the Qinling-Dabie collisional orogen, eastern China. In: Hendrix M S, Davis G A, eds. Paleozoic and Mesozoic Tectonic Evolution of Central Asia: From Continental Assembly to Intracontinental Deformation. Geol Soc Am Memoir, 194: 413-434
[5]	Wei C J, Li Y J, Yu Y, Zhang J S. 2010. Phase equilibria and metamorphic evolution of glaucophane-bearing UHP eclogites from the Western Dabieshan Terrane, Central China. J Metamorph Geol, 28: 647-666
[6]	Wu Y B, Gao S, Zhang H F, Yang S H, Jiao W F, Liu Y S, Yuan H L. 2008. Timing of UHP metamorphism in the Hong’an area, western Dabie Mountains, China: Evidence from zircon U-Pb age, trace element and Hf isotope composition. Contrib Mineral Petrol, 155: 123-133
[7]	Wu Y B, Hanchar J M, Gao S, Sylvester P J, Tubrett M, Qiu H N, Wijbrans J R, Brouwer F M, Yang S H, Yang Q J, Liu Y S, Yuan H L. 2009. Age and nature of eclogites in the Huwan shear zone, and the multi-stage evolution of the Qinling-Dabie-Sulu orogen, central China. Earth Planet Sci Lett, 277: 345-354
[8]	Wu Y B, Gao S, Liu X C, Wang J, Peng M, Gong H J, Yuan H L. 2011. Two-stage exhumation of ultrahigh-pressure metamorphic rocks from the western Dabie Orogen, central China. J Geol, 119: 15-31
[9]	Wu Y B, Zheng Y F. 2013. Tectonic evolution of a composite collision orogen: An overview on the Qinling-Tongbai-Hong’an-Dabie-Sulu orogenic belt in central China. Gondwana Res, 23: 1402-1428
[10]	Wu Y B, Zhou G G, Gao S, Liu X C, Qin Z W, Wang H, Yang J Z, Yang S H. 2014. Petrogenesis of Neoarchean TTG rocks in the Yangtze Craton and its implication for the formation of Archean TTGs. Precambrian Res, 254: 73-86
[11]	Xiang H, Zhang L, Zhong Z Q, Santosh, M, Zhou H W, Zhang H F, Zheng J P, Zheng S. 2012. Ultrahigh-temperature metamorphism and anticlockwise P-T-t path of Paleozoic granulites from north Qinling-Tongbai orogen, central China. Gondwana Res, 21: 559-576
[12]	Xiang H, Zhong Z Q, Li Y, Qi M, Zhou H W, Zhang L, Zhang Z M, Santosh M. 2014. Sapphirine-bearing granulites from the Tongbai orogen, China: Petrology, phase equilibria, zircon U-Pb geochronology and implications for Paleozoic ultrahigh temperature metamorphism. Lithos, 208-209: 446-461
[13]	Xie S W, Wu Y B, Zhang Z M, Qin Y C, Liu X C, Wang H, Qin Z W, Liu Q, Yang S H. 2012. U-Pb ages and trace elements of detrital zircons from Early Cretaceous sedimentary rocks in the Jiaolai Basin, north margin of the Sulu UHP terrane: Provenances and tectonic implications. Lithos, 154: 346-360
[14]	Xie Z, Zheng Y F, Zhao Z F, Wu Y B, Wang Z R, Chen J F, Liu X M, Wu F Y. 2006. Mineral isotope evidence for the contemporaneous process of Mesozoic granite emplacement and gneiss metamorphism in the Dabie orogen. Chem Geol, 231: 214-235
[15]	Xu H J, Ma C Q, Ye K. 2007. Early Cretaceous granitoids and their implications for the collapse of the Dabie orogen, eastern China: SHRIMP zircon U-Pb dating and geochemistry. Chem Geol, 240: 238-259
[16]	Xue F, Lerch F, Kr？ner A, Reischmann T. 1996a. Tectonic evolution of the East Qinling Mountains, China, in the Palaeozoic: A review and new tectonic model. Tectonophysics, 253: 271-284
[17]	Xue F, Kr？ner A, Reischmann T, Lerch F. 1996b. Palaeozoic pre- and post-collision calc-alkaline magmatism in the Qinling orogenic belt, central China, as documented by zircon zges on granitoid rocks. J Geol Soc London, 153: 409-417
[18]	Xue F, Rowley D B, Tucker R D, Peng Z X. 1997. U-Pb zircon ages of granitoid rocks in the North Dabie complex, eastern Dabie Shan, China. J Geol, 105: 744-753
[19]	Yan Z, Wang Z Q, Yan Q R, Wang T, Guo X Q. 2012. Geochemical constraints on the provenance and depositional setting of the Devonian Liuling Group, East Qinling Mountains, central China: Implications for the tectonic evolution of the Qinling orogenic belt. J Sediment Res, 82: 9-20
[20]	Zhai X M, Day H W, Hacker B R, You Z D. 1998. Paleozoic metamorphism in the Qinling orogen, Tongbai Mountains, central China. Geology, 26: 371-374
[21]	Zhang H F, Gao S, Zhang L, Zhong Z Q, Ling W L, Wang L S. 1998. Granulite genesis and tectonic evolution in Tongbai area: Single zircon evaporation ages and Nd isotopic geochemistry. J China Univ Geosci, 9: 174-179
[22]	Zhang H F, Gao S, Zhong Z Q, Zhang B R, Zhang L, Hu S H. 2002. Geochemical and Sr-Nd-Pb isotopic compositions of Cretaceous granitoids: Constraints on tectonic framework and crustal structure of the Dabieshan ultrahigh pressure metamorphic belt, China. Chem Geol, 186: 281-299
[23]	Zhang H F, Zhang B R, Zhong Z Q, Suo S T, Zhang H Z, Wang L S. 2003. Pb isotopic geochemical study on the crustal structure of Tongbai Shan. Progress Natural Sci, 13: 63-68
[24]	Zhang H F, Zhong Z Q, Gao S, Zhang B R, Zhang L, Hu S H, Hou Q Y. 2004. Pb and Nd isotopic composition of the Jigongshan granite: Constraints on crustal structure of Tongbaishan in the middle part of the Qinling-Tongbai-Dabie orogenic belt, central China. Lithos, 73: 215-227
[25]	Zhang J, Chen Y J, Yang Y, Deng J. 2011. Lead isotope systematics of the Weishancheng Au-Ag belt, Tongbai Mountains, central China: Implications for ore genesis. Inter Geol Rev, 53: 656-676
[26]	Zhang R Y, Liou J G. 1994. Coesite-bearing eclogite in Henan Province, central China: Detailed petrography, glaucophane stability and P-T path. Eur J Mineral, 6: 217-233
[27]	Zhao Z F, Zheng Y F, Wei C S, Wu Y B, Chen F K, Jahn B M. 2005. Zircon U-Pb age, element and C-O isotope geochemistry of post-collisional mafic-ultramafic rocks from the Dabie orogen in east-central China. Lithos, 83: 1-28
[28]	Zheng Y F, Zhou J B, Wu Y-B, Xie Z. 2005. Low-grade metamorphic rocks in the Dabie-Sulu orogenic belt: A passive-margin accretionary wedge deformed during continent subduction. Inter Geol Rev, 47: 851-871
[29]	Zheng Y F. 2012. Metamorphic chemical geodynamics in continental subduction zones. Chem Geol, 328: 5-48
[30]	Zheng Y F, Xiao W J, Zhao G C. 2013. Introduction to tectonics of China. Gondwana Res, 23: 1189-1206
[31]	Zhou L G, Xia Q X, Zheng Y F, Chen R X. 2011. Multistage growth of garnet in ultrahigh-pressure eclogite during continental collision in the Dabie orogen: Constrained by trace elements and U-Pb ages. Lithos, 127: 101-127
[32]	Zhou L G, Xia Q X, Zheng Y F, Hu Z C. 2014. Polyphase growth of garnet in eclogite from the Hong’an orogen: Constraints from garnet zoning and phase equilibrium. Lithos, 206-207: 79-99
[33]	Zhou L G, Xia Q X, Zheng Y F, Chen R X, Hu Z C, Yang Y H. 2015. Tectonic evolution from oceanic subduction to continental collision during the closure of Paleotethyan ocean: Geochronological and geochemical constraints from metamorphic rocks in the Hong’an orogen. Gondwana Res, http: //dx.doi.org/10.1016/j.gr.2014.03.009.
[34]	Zhu X Y, Chen F K, Li S Q, Yang Y Z, Nie H, Siebel W, Zhai M G. 2011. Crustal evolution of the North Qinling terrain of the Qinling Orogen, China: Evidence from detrital zircon U-Pb ages and Hf isotopic composition. Gondwana Res, 20: 194-204
[35]	张国伟, 张本仁, 袁学诚, 肖庆辉, 等. 2001. 秦岭造山带与大陆动力学. 北京: 科学出版社. 885
[36]	张国伟, 董云鹏, 赖绍聪, 郭安林, 孟庆任, 刘少锋, 程顺有, 姚安平, 张宗清, 裴先治, 李三忠. 2003. 秦岭-大别造山带南缘勉略构造带与勉略缝合带. 中国科学D辑: 地球科学, 33: 1121-1135
[37]	张宏飞, 高山, 张本仁. 2001. 大别山地壳结构的Pb同位素地球化学示踪. 地球化学, 30: 395-401
[38]	张利, 周炼, 王林森, 凌文黎. 2001. 桐柏北部黄岗侵入杂岩岛弧构造环境的厘定. 矿物岩石地球化学通报, 20: 245-247
[39]	赵子福, 郑永飞. 2009. 俯冲大陆岩石圈重熔: 大别-苏鲁造山带中生代岩浆岩成因. 中国科学D辑: 地球科学, 39: 888-909
[40]	郑永飞, 叶凯, 张立飞. 2009. 发展板块构造: 从洋壳俯冲到大陆碰撞. 科学通报, 54: 1799-1803
[41]	郑永飞, 赵子福, 陈伊翔. 2013. 大陆俯冲隧道过程: 大陆碰撞过程中的板块界面相互作用. 科学通报, 58: 2233-2239
[42]	Bader T, Franz L, Ratschbacher L, de Capitani C, Webb A A G, Yang Z, Pf？nder J A, Hofmann M, Linnemann U. 2013a. The heart of China revisited: II Early Paleozoic (ultra)high-pressure and (ultra)high-temperature metamorphic Qinling orogenic collage. Tectonics, 32: 922-947
[43]	Bader T, Ratschbacher L, Franz L, Yang Z, Hofmann M, Linnemann U, Yuan H L. 2013b. The heart of China revisited: I. Proterozoic tectonics of the Qin mountains in the core of supercontinent Rodinia. Tectonics, 32: 661-687
[44]	Brouwer F M, Groen M, Nebel O, Wijbrans J R, Qiu H N, Yang Q J, Zhao L H, Wu Y B. 2011. Coherence of the Dabie Shan UHPM terrane investigated by Lu-Hf and 40Ar/39Ar dating of eclogites. In: Dobrzhinetskaya L F, Faryad S W, Wallis S, et al., eds. UHP Metamorphism, 25 Years After Findings of Coesite and Diamond. Amsterdam: Elsevier. 325-357
[45]	Brown M. 2007. Metamorphic conditions in orogenic belts: A record of secular change. Inter Geol Rev, 49: 193-234
[46]	Brown M. 2008. Characteristic thermal regimes of plate tectonics and their metamorphic imprint throughout Earth history. In: Condie K, Pease V, eds. When Did Plate Tectonics Begin? Geol Soc Am Spec Pap, 440: 97-128
[47]	Brown M. 2009. Metamorphic patterns in orogenic systems and the geological record. In: Cawood P A, Kr？ner A, eds. Earth Accretionary Systems in Space and Time. Geol Soc London Spec Pub, 318: 37-74
[48]	Bryant D L, Ayers J C, Gao S, Miller C F, Zhang H F. 2004. Geochemical, age, and isotopic constraints on the location of the Sino-Korean/Yangtze suture and evolution of the Northern Dabie complex, east central China. Geol Soc Am Bull, 116: 698-717
[49]	Cawood P A, Kroner A, Collins W J, Kusky T M, Mooney W D, Windley B F. 2009. Accretionary orogens through Earth history. In: Cawood P A, Kr？ner A, eds. Earth Accretionary Systems in Space and Time. Geol Soc London Spec Pub, 318: 1-36
[50]	Chen F K, Guo J H, Jiang L L, Siebel W, Cong B, Satir M. 2003. Provenance of the Beihuaiyang lower-grade metamorphic zone of the Dabie ultrahigh-pressure collisional orogen, China: Evidence from zircon ages. J Asian Earth Sci, 22: 343-352
[51]	Chen L Y, Liu X C, Qu W, Hu J. 2014. U-Pb zircon ages and geochemistry of the Wuguan complex in the Qinling orogen, central China: Implications for the late Paleozoic tectonic evolution between the Sino-Korean and Yangtze cratons. Lithos, 192-195: 192-207
[52]	Cheng H, King R L, Nakamura E, Vervoort J D, Zheng Y F, Ota T, Wu Y B, Kobayashi K, Zhou Z Y. 2009. Transitional time of oceanic to continental subduction in the Dabie orogen: Constraints from U-Pb, Lu-Hf, Sm-Nd and Ar-Ar multichronometric dating. Lithos, 110: 327-342
[53]	Cheng H, DuFrane S A, Vervoort J D, Nakamura E, Li Q L, Zhou Z Y. 2010a. The Triassic age for oceanic eclogites in the Dabie orogen: Entrainment of oceanic fragments in the continental subduction. Lithos, 117: 82-98
[54]	Cheng H, DuFrane S A, Vervoort J D, Nakamura E, Zheng Y F, Zhou Z Y. 2010b. Protracted oceanic subduction prior to continental subduction: New Lu-Hf and Sm-Nd geochronology of oceanic-type high-pressure eclogite in the western Dabie orogen. Am Miner, 95: 1214-1223
[55]	Cheng H Zhang C, Vervoort J D, Wu Y B, Zheng Y F, Zheng S, Zhou Z Y. 2011. New Lu-Hf geochronology constraints the onset of continental subduction in the Dabie orogen. Lithos, 121: 41-54
[56]	Cheng H, Zhang Z, Vervoort J D, Zhou Z Y. 2013. New Lu-Hf and Sm-Nd geochronology constraints the subduction of oceanic crust during the Carboniferous-Permian in the Dabie orogen. J Asian Earth Sci, 63: 139-150
[57]	Cheng H, Vervoort J D. 2015. Combined geochemistry and geochronology constrains coupled subduction of oceanic and continental crust in the Huwan shear zone, central China. Am Miner, 100: 181-194
[58]	Cui J J, Liu X C, Dong S W, Hu J M. 2012. U-Pb and 40Ar/39Ar geochronology of the Tongbai complex, central China: Implications for Cretaceous exhumation and lateral extrusion of the Tongbai-Dabie HP/UHP terrane. J Asian Earth Sci, 47: 155-170
[59]	Cui W Y, Wang X Y. 1995. Eclogites of southern Henan and northern Hubei Provinces, central China. Island Arc, 4: 347-361
[60]	Li S Z, Kusky T M, Zhao G C, Liu X C, Zhang G W, Kopp H, Wang L. 2010. Two-stage Triassic exhumation of HP-UHP terranes in the western Dabie orogen of China: Constraints from structural geology. Tectonophysics, 490: 267-293
[61]	Li S Z, Kusky T M, Zhao G C, Liu X C, Wang L, Kopp H, Hoernle K, Zhang G W, Dai L M. 2011. Thermochronological constraints on two-stage extrusion of HP/UHP terranes in the Dabie-Sulu orogen, east-central China. Tectonophysics, 504: 25-42
[62]	Lin W, Shi Y, Wang Q. 2009. Exhumation tectonics of the HP-UHP orogenic belt in eastern China: New structural-petrological insights from the Tongcheng massif, eastern Dabieshan. Lithos, 109: 285-303
[63]	Liou J G, Zhang R Y, Wang X M, Eide E A, Ernst W G, Maruyama S. 1996. Metamorphism and tectonics of high-pressure and ultra-high-pressure belts in the Dabie-Sulu region, China. In: Yin A, Harrison M T, eds. The Tectonic Evolution of Asia. Cambridge: Cambridge University Press. 300-344
[64]	Liu J B, Ye K. 2004. Transformation of garnet epidote amphibolite to eclogite, western Dabie Mountains, China. J Metamorph Geol, 22: 383-394
[65]	Liu, J B, Ye K, Sun M. 2006. Exhumation P-T path of UHP eclogites in the Hong’an area, western Dabie Mountains, China. Lithos, 89: 154-173
[66]	Liu J B, Zhang L M. 2013. Neoproterozoic low to negative 18O volcanic and intrusive rocks in the Qinling Mountains and their geological significance. Precambrian Res, 230: 138-167
[67]	Liu X, Li S Z, Suo Y H, Liu X C, Dai L M, Santosh. 2011. Structural anatomy of the exhumation of high-pressure rocks: Constraints from the Tongbai Collisional Orogen and surrounding units. Geol J, 46: 156-172
[68]	Liu X, Li S Z, Suo Y H, Liu X C, Dai L M, Santosh. 2012. Structural analysis of the northern Tongbai Metamorphic Terranes, Central China: Inplications for Paleozoic accretionary process on the southern margin of the North China Craton. J Asian Earth Sci, 47: 143-154
[69]	Liu X C, Wei C J, Li S Z, Dong S W, Liu J M. 2004a. Thermobaric structure of a traverse across western Dabieshan: Implications for collision tectonics between the Sino-Korean and Yangtze cratons. J Metamorph Geol, 22: 361-379
[70]	Liu X C, Jahn B M, Liu D Y, Dong S W, Li S Z. 2004b. SHRIMP U-Pb zircon dating of a metagabbro and eclogites from western Dabieshan (Hong’an block), China, and its tectonic implications. Tectonophysics, 394: 171-192
[71]	Liu X C, Jahn B M, Dong S W, Lou Y X, Cui J J. 2008. High-pressure metamorphic rocks from Tongbaishan, central China: U-Pb and 40Ar/39Ar age constraints on the provenance of protoliths and timing of metamorphism. Lithos, 105: 301-318
[72]	Liu X C, Jahn B M, Cui J J, Li S Z, Wu Y B, Li X H. 2010. Triassic retrograded eclogites and Cretaceous gneissic granites in the Tongbai Complex, central China: Implications for the architecture of the HP/UHP Tongbai-Dabie-Sulu collision zone. Lithos, 119: 211-237
[73]	Liu X C, Jahn B M, Hu J, Li S Z, Liu X, Song B. 2011a. Metamorphic patterns and SHRIMP zircon ages of medium-to-high grade rocks from the Tongbai orogen, central China: Implications for multiple accretion/collision processes prior to terminal continental collision. J Metamorph Geol, 29: 979-1002
[74]	Liu X C, Jahn B M, Li S Z, Liu Y S. 2013. U-Pb zircon age and geochemical constraints on tectonic evolution of the Paleozoic accretionary orogenic system in the Tongbai orogen, central China. Tectonophysics, 599: 67-88
[75]	Liu X-C, Wu Y B, Gao S, Wang J, Peng M, Gong H J, Liu Y S, Yuan H L. 2011b. Zircon U-Pb and Hf evidence for coupled subduction of oceanic and continental crust during the Carboniferous in the Huwan shear zone, western Dabie orogen, central China. J Metamorph Geol, 29: 233-249
[76]	Liu X-C, Wu Y B, Gao S, Peng M, Wang J, Wang H, Gong H J, Yuan H L. 2012. Triassic high-pressure metamorphism in the Huwan shear zone: Tracking the initial subduction of continental crust in the whole Dabie orogen. Lithos, 136-139: 60-72
[77]	Mattauer M, Matte P, Malavieille J, Tapponnier P, Maluski H, Xu Z Q, Lu Y L, Tang Y Q. 1985. Tectonics of the Qinling belt: Build-up and evolution of eastern Asia. Nature, 317: 496-500
[78]	McKenzie D M, Priestley K. 2008. The influence of lithospheric thickness variations on continental evolution. Lithos, 102: 1-11
[79]	Meng Q R, Zhang G W. 1999. Timing of collision of the North and South China blocks: controversy and reconciliation. Geology, 27: 123-126
[80]	Meng Q R, Zhang G W. 2000. Geologic framework and tectonic evolution of the Qinling orogen, central China. Tectonophysics, 323: 183-196
[81]	Meng Q R, Wang E, Hu J M. 2005. Mesozoic sedimentary evolution of the northwest Sichuan basin: implication for continued clockwise rotation of the South China block. Geol Soc Am Bull, 117: 396-410
[82]	O’Brien P J. 2001. Subduction followed by collision: Alpine and Himalayan examples. Phys Earth Planet Int, 127: 277-291
[83]	Okay A I, Seng？r A M C, Satir M. 1993. Tectonics of an ultrahigh-pressure metamorphic terrane: The Dabie Shan/Tongbai Shan orogen, China. Tectonics, 12: 1320-1334
[84]	Peters T J, Ayers J C, Gao S, Liu X M. 2013. The origin and response of zircon in eclogite to metamorphism during themulti-stage evolution of the Huwan Shear Zone, China: Insights from Lu-Hf and U-Pb isotopic and trace element geochemistry. Gondwana Res, 23: 726-747.
[85]	Ratschbacher L, Hacker B R, Webb L E, McWilliam M, Ireland T, Dong S W, Calvert A, Chateigner D, Wenk H R. 2000. Exhumation of the ultrahigh-pressure continental crust in east central China: Cretaceous and Cenozoic unroofing and the Tan-Lu fault. J Geophys Res, 105: 13303-13338
[86]	Ratschbacher L, Hacker B R, Calvert A, Webb L E, Grimmer J C, McWilliams M O, Ireland T, Dong S W, Hu J M. 2003. Tectonics of the Qinling (Central China): Tectonostratigraphy, geochronology, and deformation history. Tectonophysics, 366: 1-53
[87]	Ratschbacher L, Franz L, Enkelmann E, Jonckheere R, P？rschke A, Hacker B R, Dong S W, Zhang Y Q. 2006. The Sino-Korean-Yangtze suture, the Huwan detachment, and the Paleozoic-Tertiary exhumation of (ultra)high-pressure rocks along the Tongbai-Xinxian-Dabie Mountains. In: Hacker B R, McClelland W C, Liou J G, eds. Ultrahigh-pressure Metamorphism: Deep Continental Subduction. Geol Soc Am Spec Pap, 403: 45-75
[88]	Sun W D, Williams I S, Li S G. 2002. Carboniferous and Triassic eclogites in the western Dabie Mountains, east-central China: Evidence for protracted convergence of the North and South China Blocks. J Metamorph Geol, 20: 873-886
[89]	Tang J, Zheng Y F, Wu Y B, Gong B. 2006. Zircon SHRIMP U-Pb dating, C and O isotopes for impure marbles in the Jiaobei terrane of the Sulu orogen: Implication for its tectonic affinity. Precambrian Res, 144: 1-18
[90]	Wang H, Wu Y B, Gao S, Zhang H F, Liu X-C, Gong H J, Peng M, Wang J, Yuan H L. 2011. Silurian granulite-facies metamorphism, and coeval magmatism and crustal growth in the Tongbai orogen, central China. Lithos, 125: 249-271
[91]	陈龙耀, 罗玉凌, 刘晓春, 曲玮, 胡娟. 2014. 南秦岭刘岭群砂岩碎屑锆石LA-ICP-MS U-Pb年龄及其构造意义. 地质通报, 33: 1363-1378
[92]	第五春荣, 孙勇, 刘良, 张成立, 王洪亮. 2010. 北秦岭宽坪岩群的解体及新元古代N-MORM. 岩石学报, 26: 2025-2038
[93]	冯益民, 曹宣铎, 张二朋. 2004. 勉县-略阳带大地构造属性之探讨. 地质论评, 50: 295-303
[94]	高联达, 刘志刚. 1988. 河南信阳群南湾组徽体化石的发现及其地质意义. 地质论评, 34: 421
[95]	胡健民, 孟庆任, 陈虹, 武国利, 渠洪杰, 高卫, 陈文. 2011. 秦岭造山带内宁陕断裂带构造演化及其意义. 岩石学报, 27: 657-671
[96]	胡娟, 刘晓春, 陈龙耀, 曲玮, 李怀坤, 耿建珍. 2013. 扬子克拉通北缘约2.5 Ga岩浆事件: 来自南秦岭陡岭杂岩锆石U-Pb年代学和Hf同位素证据. 科学通报, 58: 3579-3588
[97]	黄少英, 徐备, 王长秋, 湛胜, 邓荣敬. 2006. 桐柏造山带几何学、运动学和演化. 中国科学D辑: 地球科学, 36: 242-251
[98]	简平, 杨巍然, 李志昌, 周慧芳. 1997. 大别山西部熊店加里东期榴辉岩——同位素年代学的证据. 地质学报, 71: 133-141
[99]	简平, 刘敦一, 杨巍然, Williams I S. 2000. 大别山西部河南罗山熊店加里东期榴辉岩锆石特征及SHRIMP分析结果. 地质学报, 74: 259-264
[100]	江思宏, 聂凤军, 方东会, 刘翼飞. 2009a. 河南桐柏围山城地区侵入岩年代学与地球化学特征. 地质学报, 83: 1011-1029
[101]	江思宏, 聂凤军, 方东会, 刘翼飞, 张万益, 许东青, 张志军. 2009b. 河南桐柏围山城地区主要金银矿床的成矿年代学研究. 矿床地质, 28: 63-72
[102]	李瑞保, 裴先治, 丁仨平, 李佐臣, 冯建赟, 孙雨, 张亚峰, 刘战庆. 2009. 西秦岭南缘勉略带琵琶寺基性火山岩LA-ICP-MS锆石U-Pb年龄及其构造意义. 地质学报, 83: 1612-1623
[103]	李任伟, 孟庆任, 李双应. 2005. 大别山及邻区侏罗和石炭纪时期盆-山耦合: 来自沉积记录的认识. 岩石学报, 21: 1133-1143
[104]	李三忠, 赖绍聪, 张国伟, 李亚林, 程顺有. 2003. 秦岭勉(县)略(阳)缝合带及南秦岭地块的变质动力学研究. 地质科学, 38: 137-154
[105]	林伟, 冀文斌, 石永红, 褚杨, 李秋立, 陈泽超, 刘飞, 王清晨. 2013. 高压-超高压变质岩石多期构造折返: 以桐柏-红安-大别造山带为例. 科学通报, 58: 2259-2265
[106]	刘晓春, 康维国, 周高志, 韩守荣. 1989. 桐柏山-大别山南缘蓝片岩主要矿物研究及变质作用演化. 长春地质学院学报(鄂皖蓝片岩带地质专辑), 41-56
[107]	刘晓春, 李三忠, 刘建民, 董树文, 薛怀民, 曲玮. 2002. 西大别横穿造山带实测地质剖面的基本构造样式. 地质通报, 21: 536-540
[108]	刘晓春, 娄玉行, 董树文. 2005. 桐柏山地区低温榴辉岩变质作用的P-T轨迹. 岩石学报, 21: 1081-1093
[109]	刘晓春, 江博明, 李三忠, 崔建军, 刘鑫, 娄玉行, 曲玮. 2011. 桐柏高压变质地体: 对桐柏-大别-苏鲁高压/超高压变质带构造框架和俯冲/折返机制的制约. 岩石学报, 27: 1151-1162
[110]	刘晓春, 江博明, 李三忠. 2013. 大陆岩板俯冲与折返的穿时性: 桐柏造山带晚二叠-三叠纪高压变质地体提供的制约. 科学通报, 58: 2251-2258
[111]	刘小驰, 吴元保, 汪晶, 彭敏, 焦文放. 2009. 西大别浒湾变质带洋壳和陆壳耦合俯冲的锆石U-Pb年龄纪录及其动力学意义. 岩石学报, 25: 2209-2223
[112]	刘贻灿, 李曙光, 古晓峰, 侯振辉. 2006. 北淮阳王母观橄榄辉长岩锆石SHRIMP U-Pb年龄及其地质意义. 科学通报, 51: 2175-2180
[113]	刘贻灿, 刘理湘, 古晓峰, 李曙光, 刘佳, 宋彪. 2010. 大别山北淮阳带西段新元古代浅变质花岗岩的发现及其大地构造意义. 科学通报, 55: 2391-2399
[114]	陆松年, 李怀坤, 陈志宏, 郝国杰, 周红英, 郭进京, 牛广华, 相振群. 2003. 秦岭中-新元古代地质演化及对Rodinia超级大陆事件的响应. 北京: 地质出版社. 194
[115]	牛宝贵, 富云莲, 刘志刚, 任纪舜, 陈文. 1994. 桐柏-大别山主要构造热事件及40Ar/39Ar地质定年研究. 地球学报, 15: 20-34
[116]	曲玮, 刘晓春, 胡娟, 李怀坤, 耿建珍. 2013. 桐柏地区秦岭岩群中碱性岩脉的锆石U-Pb年龄: 对麻粒岩相变质时代的约束. 岩石学报, 29: 3080-3086
[117]	任纪舜, 姜春发, 张正坤, 秦德余. 1980. 中国大地构造及其演化. 北京: 科学出版社. 124
[118]	任纪舜, 陈廷愚, 牛宝贵, 刘志刚, 刘凤仁. 1990. 中国东部及邻区大陆岩石圈的构造演化与成矿. 北京: 科学出版社. 205
[119]	任纪舜, 张正坤, 牛宝贵, 刘志刚. 1991. 论秦岭造山带——中朝与扬子陆块的拼合过程. 见: 叶连俊, 钱祥麟, 张国伟, 主编. 秦岭造山带学术讨论会论文选集. 西安: 西北大学出版社. 99-110
[120]	魏春景, 杨崇辉, 张寿广, 李荣社. 1998. 南秦岭佛平地区麻粒岩的发现及其地质意义. 科学通报, 43: 982-985
[121]	魏春景, 吴玉新, 倪云燕, 陈斌, 王式洸, 常宗广. 1999. 河南桐柏地区榴辉岩的特征及其地质意义. 科学通报, 44: 1882-1885
[122]	魏春景, 张翠光. 2002. 陆-陆碰撞造山带中压型变质作用的P-T轨迹——以南秦岭佛坪地区为例. 岩石矿物学杂志, 21: 356-362
[123]	吴元保, 郑永飞. 2013. 华北陆块古生代南向增生与秦岭-桐柏-红安造山带构造演化. 科学通报, 58: 2246-2250
[124]	许光, 王二七. 2010. 桐柏杂岩的中生代隆升机制及其与南阳盆地沉降的耦合关系. 地质科学, 45: 626-652
[125]	闫全人, 王宗起, 闫臻, 向忠全, 陈隽璐, 王涛. 2007. 秦岭勉略构造混杂带康县-勉县段蛇绿岩块-镁铁质岩块的SHRIMP年代及其意义. 地质论评, 53: 755-764
[126]	闫全人, 王宗起, 闫臻, 王涛, 陈隽璐, 向忠金, 张宗清, 姜春发. 2008. 秦岭造山带宽坪群中的变铁镁质岩的成因、时代及其构造意义. 地质通报, 27: 1475-1492
[127]	杨崇辉, 魏春景, 张寿广, 李惠民, 万渝生, 李荣社. 1999. 南秦岭佛坪地区麻粒岩相岩石锆石U-Pb年龄. 地质论评, 45: 173-179
[128]	杨栋栋, 李双应, 赵大千, 王松, 杜叶龙, 赵万维. 2012. 大别山北缘石炭系碎屑岩地球化学及碎屑锆石年代学分析及其对物源区大地构造属性判别的制约. 岩石学报, 28: 2619-2628
[129]	张本仁, 张宏飞, 赵志丹, 凌文黎. 1996. 东秦岭及邻区壳幔地球化学分区和演化及其大地构造意义. 中国科学D辑: 地球科学, 26: 201-208
[130]	张本仁, 韩吟文, 许继峰, 欧阳建平. 1998. 北秦岭新元古代前属扬子板块的地球化学证据. 高校地质学报, 4: 369-382
[131]	张国伟, 等. 1988. 秦岭造山带形成及其演化. 西安: 西北大学出版社. 192
[132]	Dong Y P, Zhang G W, Neubauer F, Liu X M, Genser J, Hauzenberger C. 2011a. Tectonic evolution of the Qinling orogen, China: Review and synthesis. J Asian Earth Sci, 41: 213-237
[133]	Dong Y P, Zhang G W, Hauzenberger C, Neubauer F, Yang Z, Liu X M. 2011b. Paleozoic tectonics and evolutionary history of the Qinling orogen: Evidence from geochemistry and geochronology of ophiolite and related volcanic rocks. Lithos, 122: 39-56
[134]	Dong Y P, Genser J, Neubauer F, Zhang G W, Liu X M, Yang Z, Heberer B. 2011c. U-Pb and 40Ar/39Ar geochronological constraints on the exhumation history of the North Qinling terrane, China. Gondwana Res, 19: 881-893
[135]	Dong Y P, Liu X M, Zhang G W, Chen Q, Zhang X N, Li W, Yang C. 2012. Triassic diorites and granitoids in the Foping area: Constraints on the conversion from subduction to collision in the Qinling orogen, China. J Asian Earth Sci, 47: 123-142
[136]	Dong Y P, Liu X M, Neubauer F, Zhang G W, Tao N, Zhang Y G, Zhang X N, Li W. 2013. Timing of Paleozoic amalgamation between the North China and South China Blocks: Evidence from detrital zircon U-Pb ages. Tectonophysics, 586: 173-191
[137]	Dong Y P, Yang Z, Liu X M, Zhang X N, He D F, Li W, Zhang F F, Sun S S, Zhang H F, Zhang G W. 2014. Neoproterozoic amalgamation of the Northern Qinling terrain to the North China Craton: Constraints from geochronology and geochemistry of the Kuanping ophiolite. Precambrian Res, 255: 77-95
[138]	Eide E A, Liou J G. 2000. High-pressure blueschists and eclogites in Hong’an: A frame work for addressing the evolution of high- and ultrahigh-pressure rocks in central China. Lithos, 52: 1-22
[139]	Ernst W G, Tsujimori T, Zhang R, Liou J G. 2007. Permo-Triassic collision, subduction-zone metamorphism, and tectonic exhumation along the East Asian continental margin. Ann Rev Earth Planet Sci, 35: 73-110
[140]	Faure M, Lin W, Shu L S, Sun Y, Sch？rer U. 1999. Tectonics of the Dabieshan (eastern China) and possible exhumation mechanism of ultra high-pressure rocks. Terra Nova, 11: 251-258
[141]	Faure M, Lin W, Sch？rer U, Shu L S, Sun Y, Arnaud N. 2003. Continental subduction and exhumation of the UHP rocks: Structural and geochronological insights from the Dabieshan (East China). Lithos, 70: 213-241
[142]	Fu B, Zheng Y F, Touret J L R. 2002. Petrological, isotopic and fluid inclusion studies of eclogites from Sujiahe, NW Dabie Shan (China). Chem Geol, 187: 107-128
[143]	Hacker B R, Ratschbacher L, Webb L E, Dong S W. 1995. What brought them up? Exhumation of the Dabie Shan ultrahigh-pressure rocks. Geology, 23: 743-746
[144]	Hacker B R, Ratschbacher L, Webb L E, McWilliams M O, Ireland T, Calvert A, Dong S W, Wenk H R, Chateigner D. 2000. Exhumation of ultrahigh-pressure continental crust in east central China: Late Triassic-Early Jurassic tectonic unroofing. J Geophys Res, 105: 13339-13364
[145]	Hacker B R, Ratschbacher L, Liou J G. 2004. Subduction, collision and exhumation in the ultrahigh-pressure Qinling-Dabie orogen. In: Malpas J, Fletcher C J N, Ali J R, et al., eds. Aspects of the Tectonic Evolution of China. Geol Soc London Spec Pub, 226: 157-175
[146]	Jahn B M, Wu F Y, Lo C H, Tsai C H. 1999. Crustal-mantle interaction induced by deep subduction of the continental crust: Geochemical and Sr-Nd isotopic evidence from post-collisional mafic-ultramafic intrusions of the northern Dabie complex, central China. Chem Geol, 157: 119-146
[147]	Jahn B M, Liu X C, Yui T F, Morin N, Coz B L M. 2005. High-pressure/ultrahigh-pressure eclogites from the Hong’an Block, east-central China: Geochemical characterization, isotope disequilibrium and geochronological controversy. Contrib Mineral Petrol, 149: 499-526
[148]	Kr？ner A, Zhang G W, Sun Y. 1993. Granulites in the Tongbai area, Qinling belt, China: Geochemistry, petrology, single zircon geochronology, and implications for the tectonic evolution of eastern Asia. Tectonics, 12: 245-255
[149]	Le Pichon X, Henry P, Goffe B. 1997. Uplift of Tibet: From eclogites to granulites-implications for the Andean Plateau and the Variscan belt. Tectonophysics, 273: 57-76
[150]	Li N, Chen Y J, Santosh M, Pirajno F. 2015. Compositional polarity of Triassic granitoids in the Qinling Orogen, China: Implication for termination of the northernmost paleo-Tethys. Gondwana Res, 27: 244-257
[151]	Li R W, Li S Y, Jin F Q, Wan Y S, Zhang S K. 2004. Provenance of Carboniferous sedimentary rocks in the northern margin of Dabie Mountains, central China and the tectonic significance: Constraints from trace elements, mineral chemistry and SHRIMP dating of zircons. Sediment Geol, 166: 245-264
[152]	Li S G, Han W, Huang F, Zheng Y F. 1998. Sm-Nd and Rb-Sr ages and geochemistry of volcanics from the Dingyuan formation in Dabie Mountains, central China: Evidence to the Paleozonic magmatic arc. Sci Geol Sin, 7: 461-470
[153]	Li S G, Huang F, Nie Y H, Han W L, Long G, Li H M, Zhang S Q, Zhang Z H. 2001. Geochemical and Geochronological constraints on the suture location between the North and South China Blocks in the Dabie orogen, central China. Phys Chem Earth, 26: 655-672
[154]	Li S Z, Kusky T M, Wang L, Zhang G W, Lai S C, Liu X C, Dong S W, Zhao G C. 2007. Collision leading to multiple-stage large-scale extrusion in the Qinling orogen: Insights from the Mianlue suture. Gondwana Res, 12: 121-143
[155]	Li S Z, Kusky T M, Liu X C, Zhang G W, Zhao G C, Wang L, Wang Y J. 2009. Two-stage collision-related extrusion of the western Dabie HP-UHP metamorphic terranes, central China: Evidence from quartz c-axis fabrics and structures. Gondwana Res, 16: 294-309

Full-Text

Contact Us

[email protected]

QQ:3279437679

WhatsApp +8615387084133