Intra-continental Orogeny: Insights from Magnetotelluric Data into the Mesozoic Uplift History of the Eastern Jiangnan Orogen in South China
Kun ZHANG
Chinese Academy of Geological Sciences, Beijing, 100037 China
Key Laboratory of Deep Earth Science and Exploration Technology of Ministry of Natural Resources
Search for more papers by this authorCorresponding Author
Qingtian LÜ
Chinese Academy of Geological Sciences, Beijing, 100037 China
Key Laboratory of Deep Earth Science and Exploration Technology of Ministry of Natural Resources
Corresponding author. E-mail: [email protected]Search for more papers by this authorJinhua ZHAO
Chinese Academy of Geological Sciences, Beijing, 100037 China
Key Laboratory of Deep Earth Science and Exploration Technology of Ministry of Natural Resources
Search for more papers by this authorJiayong YAN
Chinese Academy of Geological Sciences, Beijing, 100037 China
Key Laboratory of Deep Earth Science and Exploration Technology of Ministry of Natural Resources
Search for more papers by this authorFan LUO
East China Institute of Technology, Nanchang, 330013 China
Search for more papers by this authorZuhui MAN
Chinese Academy of Geological Sciences, Beijing, 100037 China
Key Laboratory of Deep Earth Science and Exploration Technology of Ministry of Natural Resources
China University of Geosciences (Wuhan), Wuhan, 430074 China
Search for more papers by this authorGang ZHANG
China University of Geosciences (Beijing), Beijing, 100086 China
Search for more papers by this authorFan YONG
Institute of Geophysical and Geochemical Exploration, Chinese Academy of Geological Sciences, Langfang, Hebei, 065000 China
Search for more papers by this authorKun ZHANG
Chinese Academy of Geological Sciences, Beijing, 100037 China
Key Laboratory of Deep Earth Science and Exploration Technology of Ministry of Natural Resources
Search for more papers by this authorCorresponding Author
Qingtian LÜ
Chinese Academy of Geological Sciences, Beijing, 100037 China
Key Laboratory of Deep Earth Science and Exploration Technology of Ministry of Natural Resources
Corresponding author. E-mail: [email protected]Search for more papers by this authorJinhua ZHAO
Chinese Academy of Geological Sciences, Beijing, 100037 China
Key Laboratory of Deep Earth Science and Exploration Technology of Ministry of Natural Resources
Search for more papers by this authorJiayong YAN
Chinese Academy of Geological Sciences, Beijing, 100037 China
Key Laboratory of Deep Earth Science and Exploration Technology of Ministry of Natural Resources
Search for more papers by this authorFan LUO
East China Institute of Technology, Nanchang, 330013 China
Search for more papers by this authorZuhui MAN
Chinese Academy of Geological Sciences, Beijing, 100037 China
Key Laboratory of Deep Earth Science and Exploration Technology of Ministry of Natural Resources
China University of Geosciences (Wuhan), Wuhan, 430074 China
Search for more papers by this authorGang ZHANG
China University of Geosciences (Beijing), Beijing, 100086 China
Search for more papers by this authorFan YONG
Institute of Geophysical and Geochemical Exploration, Chinese Academy of Geological Sciences, Langfang, Hebei, 065000 China
Search for more papers by this authorAbout the first author:
ZHANG Kun, male, born in 1983 in Tianjin; Ph.D.; graduated from China's University of Geosciences (Beijing); research fellow at the Chinese Academy of Geological Sciences. He is currently interested in the study of deep earth exploration and magnetotelluric techniques. E-mail: [email protected].
About the corresponding author:
LÜ Qingtian, male, born in 1964 in Nanyang, Henan Province; Ph.D.; graduated from the Changchun Institute of Geology; research fellow of the Chinese Academy of Geological Sciences. He is currently interested in the study of deep earth exploration and mineral systems. Email: [email protected].
Abstract
Despite extensive efforts to understand the tectonic evolution of the Jiangnan Orogen in South China, the orogenic process and its mechanism remain a matter of dispute. Previous geodynamic studies have mostly focused on collisional orogeny, which is commonly invoked to explain the Jiangnan Orogen. However, it is difficult for such hypotheses to reconcile all the geological and geophysical data, especially the absence of ultrahigh-pressure metamorphic rocks. Based on the magnetotelluric data, we present a group of resistivity models produced through the combination of two -dimensional and three-dimensional inversions, revealing the geo-electrical structures of Jiangnan and a typical collisional orogen. In our models, the resistive crust is separated into three parts by a prominent conductive layer with opposite dipping directions on both sides. A special thrust-nappe system, which is different from that developed in a typical collisional process, is revealed in the Jiangnan Orogen. This structure suggests a process different from the simple collisional orogeny. To interpret our observations, an ‘intra-continental orogeny’ is proposed to address the development of the Jiangnan Orogen in the Mesozoic. Furthermore, this ‘reworked’ process may contain at least two stages caused by the decoupling of the lithosphere, which is revealed by an extra conductive layer beneath Jiangnan.
Supporting Information
Supplementary material to this article can be found online at https://doi.org/10.1111/1755-6724.14950.
| Filename | Description |
|---|---|
| acgs14950-sup-0001-S1.docx629.4 KB | Supplement Material |
Please note: The publisher is not responsible for the content or functionality of any supporting information supplied by the authors. Any queries (other than missing content) should be directed to the corresponding author for the article.
References
- Caldwell, T.G., Bibby, H.M., and Brown, C., 2004. The magnetotelluric phase tensor. Geophysical Journal International, 158(2): 457–469.
- Chang, Y.F., Liu, X.P., and Wu, Y.C., 1991. The Copper-iron Belt of the Lower and Middle Reaches of the Changjiang River. Beijing: Geological Publishing House, 1–379 (in Chinese).
- Chang, Y.F., Dong, S.W., and Hong, D.Z., 1996. On tectonics of “polybasement with one cover” in Middle–Lower Yangtze Craton, China. Volcanology & Mineral Resources, 17(S1): 1–15 (in Chinese with English abstract).
- Charvet, J., Shu, L.S., Shi, Y.S., Guo, L.Z., and Faure, M., 1996. The building of South China: Collision of Yangtze and Cathaysia blocks, problems and tentative answers. Journal of Southeast Asian Earth Science, 13(3–5): 223–235.
- Chen, J.F., Foland, K.A., Xing, F.M., Xu, X., and Zhou, T.X., 1991. Magmatism along the southeast margin of the Yangtze Block: Precambrian collision of the Yangtze and Cathaysia blocks of China. Geology, 19(8): 815–818.
- Dong, S.W., Ma, L.C., Liu, G., Xue, H.M., Shi, W., and Li, J.H., 2011. On dynamics of the metallogenic belt of the Middle–Lower Reaches of the Yangtze River, eastern China. Acta Geologica Sinica, 85(5): 612–625 (in Chinese with English abstract).
- Dong, H., Wei, W.B., Jin, S., Ye, G.F., Zhang, L.T., Jing, J.E., Yin, Y.T., Xie, C.L., and Jones, A., 2016. Extensional extrusion: Insights into south-eastward expansion of Tibetan Plateau from magnetotelluric array data. Earth and Planetary Science Letters, 454: 78–85.
- Faure, M., Lin, W., and Breton, N.L., 2001. Where is the North China–South China block boundary in eastern China? Geology, 29(2): 119–122.
- Ge, X., Shen, C.B., Yang, Z., Mei, L.F., Xu, S.H., Peng, L., and Liu, Z.Q., 2013. Low-temperature thermochronology Constraints on the Mesozoic–Cenozoic exhumation of the Huangling massif in the Middle Yangtze Block, Central China. Journal of Earth Science, 24(4): 541–552.
- Guo, L.Z., Shi, Y.S., and Ma, R.S., 1977. On the research method and significance of the ancient trench island arc system. Geology of Fujian, 4: 1–24 (in Chinese).
- He, L.J., Hu, S.B., and Wang, J.Y., 2001. The characteristics of the thermal structure of the lithosphere in East China. Progress in Natural Science, 11(9): 966–969 (in Chinese).
- Hsü, K.J., Sun, S., Li, J.L., Chen, H.H., Pen, H.B., and Sengor, A.M.C., 1988. Mesozoic overthrust tectonics in South China. Geology, 16(5): 418–421.
- Huang, J.Q., 1954. Main geological structural units in China. Beijing: Geological Publishing House, 1–150 (in Chinese).
- Huang, J.Q., 1959. Some opinions on the compilation of the Chinese geotectonic map. Geoscience Communication, 2: 3–8 (in Chinese).
- Huang, J.Q., 1960. A preliminary summary of the basic characteristics of geological structure in China. Acta Geologica Sinica, 40(1): 1–31 (in Chinese).
- Ichihara, H., and Mogi, T., 2009. A realistic 3-D resistivity model explaining anomalous large magnetotelluric phases: The l-shaped conductor model. Geophysical Journal International, 179(1): 14–17.
- Jiang, G.M., Zhang, G.B., Lü, Q.T., Shi, D.N., and Xu, Y., 2013. 3-D velocity model beneath the Middle–Lower Yangtze River and its implication to the deep geodynamics. Tectonophysics, 606: 36–47.
- Jones, A.G., 1992. Electrical properties of the continental lower crust. In: D.M. Fountain, R.J. Arculus, and R.W. Kay (eds.), Continental Lower Crust. Elsevier, Amsterdam, 81–143.
- Jones, A.G., 1983. On the equivalence of the “Niblett” and “Bostick” transformations in the magnetotelluric method. Journal of Geophysics, 53: 72–73.
- Lee, W.H.K., 1970. On the global variations of terrestrial heat-flow. Physics of the Earth and Planetary Interiors, 2(5): 332–341.
10.1016/0031-9201(69)90026-0 Google Scholar
- Li, S.Z., Zhao, G.C., Zhang, G.W., Liu, X.C., Dong, S.W., Wang, Y.J., Liu, X., Suo, Y.H., Dai, L.M., Jin, C., Liu, L.P., Hao, Y., Liu, E.S., Wang, J., and Wang, T., 2010. Not all folds and thrusts in the Yangtze foreland thrust belt are related to the Dabie Orogen: Insights from Mesozoic deformation south of the Yangtze River. Geological Journal, 45(5–6): 650–663.
- Li, S.Z., Zhang, G.W., Zhou, L.H., Zhao, G.C., Liu, X., Suo, Y.H., Liu, B., Jin, C., and Dai, L.M., 2011. The opposite Meso–Cenozoic intracontinental deformations under the super-convergence: Rifting and extension in the North China Craton and shortening and thrusting in the South China Craton. Earth Science Frontiers, 18(3): 79–107 (in Chinese with English abstract).
- Li, S.Z., Zhao, G.C., Dai, L.M., Liu, X., Zhou, L.L., Santosh, M., and Suo, Y.H., 2012. Mesozoic basins in eastern China and their bearing on the deconstruction of the North China Craton. Journal of Asian Earth Sciences, 47: 64–79.
- Li, X.Y., Zhu, P.M., Kusky, T.M., Gu, Y., Peng, S.B., Yuan, Y.F., and Fu, J.M., 2015. Has the Yangtze craton lost its root? A comparison between the North China and Yangtze cratons. Tectonophysics, 655: 1–14.
- Li, Y., Yuan, F., Jowitt, S.M., Deng, Y.F., Hu, X.Y., Liu, G.X., Li, X.H., and Zhou, T.F., 2020. Geochronology, petrogenesis and metallogenic implications of mineralization-related intrusive rocks in the Xuancheng ore district, eastern China. Ore Geology Reviews, 135: 103690.
- Li, C., Wang, Z., Lü, Q., Tan, Y., Li, L., and Tao, T., 2021. Mesozoic tectonic evolution of the eastern South China Block: A review on the synthesis of the regional deformation and magmatism. Ore Geology Reviews, 131: 104028.
- Ling, M.X., Wang, F.Y., Ding, X., Hu, Y.H., Zhou, J.B., Zartman, R.E., Yang, X.Y., and Sun, W., 2009. Cretaceous ridge subduction along the lower Yangtze River belt, eastern China. Economic Geology, 104(2): 303–321.
- Liu, L., Xu, X.S., and Xia, Y., 2016. Asynchronizing paleo-Pacific slab rollback beneath SE China: Insights from the episodic Late Mesozoic volcanism. Gondwana Research, 37: 397–407.
- Lü, Q.T., Yan, J.Y., Shi, D.N., Dong, S.W., Tang, J.T., Wu, M.A., and Chang, Y.F., 2013. Reflection seismic imaging of the Lujiang–Zongyang volcanic basin, Yangtze Metallogenic Belt: An insight into the crust structure and geodynamics of an ore district. Tectonophysics, 606: 60–77.
- Lü, Q.T., Dong, S.W., Shi, D.N., Tang, J.T., Jiang, G.M., and Zhang, Y.Q., 2014. Lithosphere architecture and geodynamic model of Middle and Lower Reaches of Yangtze Metallogenic Belt: A review from SinoProbe. Acta Petrologica Sinica, 30 (4): 889–906. (in Chinese with English abstract).
- Lü, Q.T., Liu, Z.D., Dong, S.W., Yan, J.Y., and Zhang, Y.Q., 2015. The nature of Yangtze River deep fault zone: Evidence for deep seismic data. Chinese Journal of Geophysics, 58(12): 4344–4359 (in Chinese with English abstract).
- Lü, Q.T., Meng, G.X., Zhang, K., Liu, Z.D., Yan, J.Y., Shi, D.N., Han, J.G., and Gong, X.J., 2021. The lithospheric architecture of the Lower Yangtze Metallogenic Belt, East China: Insights into an extensive Fe-Cu mineral system. Ore Geology Reviews, 132: 103989.
- Mao, J.R., Li, Z.L., and Ye, H.M., 2014. Mesozoic tectono-magmatic activities in South China: Retrospect and prospect. Science China: Earth Sciences, 57(12): 2853–2877.
- Newman, G.A., and Alumbaugh, D.L., 2000. Three-dimensional magnetotellutric inversion using non-linear conjugate gradients. Geophysical Journal International, 140: 410–424.
- Ni, J.L., Liu, J.L., Tang, X.L., Yang, H.B., Xia, Z.M., and Guo, Q.J., 2013. The Wulian metamorphic core complex: A newly discovered metamorphic core complex along the Sulu orogenic belt, eastern China. Journal of Earth Science, 24(3): 297–313.
- Pirajno, F., 2013. The Geology and Tectonic Settings of China's Mineral Deposits. Springer, New York.
10.1007/978-94-007-4444-8 Google Scholar
- Qi, H.S., 2019. Comparing geochemistry study of porphyry copper-gold deposits in different tectonic environments: A case study of Grasberg, Papua, Indonesia and Chating, Anhui Province. Hefei: University of Science and Technology of China (in Chinese with English abstract).
- Ren, J.S., Niu, B.G., He, Z., Xie, G., and Liu, Z.G., 1997. Tectonic frame and geodynamic evolution of eastern China. Geological Research, 29(30): 43–55 (in Chinese with English abstract).
- Rodi, W.L., Mackie, R.L., 2001. Nonlinear conjugate gradients algorithm for 2-D magnetotelluric inversion. Geophysics, 61 (1): 174–187.
- Shu, L.S., Shi, Y.S., Guo, L.Z., Charvet, J., and Sun, Y., 1995. Plate terrane structure and collisional orogeny in the middle part of Jiangnan. Nanjing: Nanjing University Press, 1–170 (in Chinese).
- Shu, L.S., Faure, M., Yu, J.H., and Jahn, B.M., 2011. Geochronological and geochemical features of the Cathaysia block (South China): New evidence for the Neoproterozoic breakup of Rodinia. Precambrian Research, 187(3–4): 263–276.
- Shu, L.S., Chen, X.Y., and Lou, F.S., 2020. Pre-Jurassic tectonics of South China. Acta Geologica Sinica, 94(2): 333–360 (in Chinese with English abstract).
- Song, C.Z., Jiang, Q.S., Li, J.H., Yan, J., Shi, Y.H., Han, C.S., Huang, W.P., and Yu, G., 2012. Relationship between structures and their controls to ores in the southern margin of Fanchang Basin in Anhui Province. Acta Petrologica Sinica, 28(10): 3197–3208 (in Chinese with English abstract).
- Wang, P.C., Li, S.Z., Liu, X., Yu, S., Liu, B., Suo, Y.H., Xue, Y.C., and An, H.T., 2012. Yanshanian fold-thrust tectonics and dynamics in the Middle–Lower Yangtze River area, China. Acta Petrologica Sinica, 28(10): 3418–3430 (in Chinese with English abstract).
- Wang, Q., Zhao, Z.H., Xiong, X.L., and Xu, J.F., 2001. Melting of the underplating basaltic lower crust: Evidence from the Shaxi adakite-like sodium-rich quartz diorite–porphyrite in Anhui Province. Geochimica, 30(4): 353–362 (in Chinese with English abstract).
- Wang, X.L., Zhou, J.C., Qiu, J.S., and Gao, J.F., 2004. Geochemistry of the Meso- to Neo-proterozoic basic-acid rocks from Hunan Province, South China: Implications for the evolution of the western Jiangnan orogen. Precambrian Research, 135: 79–103.
- Wang, X.L., Zhou, J.C., Chen, X., Zhang, F.F., and Sun, Z.M., 2017. Formation and evolution of the Jiangnan Orogen. Bulletin of Mineralogy, Petrology and Geochemistry, 36(5): 714–735 (in Chinese with English abstract).
- Wang, Y.J., Zhang, F.F., Fan, W.M., Zhang, G.W., Chen, S.Y., Cawood, P.A., and Zhang, A.M., 2010. Tectonic setting of the South China Block in the early Paleozoic: Resolving intra-continental and ocean closure models from detrital zircon U-Pb geochronology. Tectonics, 29(6): TC6020.
- Wong, J., Sun, M., Xing, G.F., Li, X.H., Zhao, G.C., Wong, K., and Wu, F.Y., 2011. Zircon U-Pb and Hf isotopic study of Mesozoic felsic rocks from eastern Zhejiang, South China: Geochemical contrast between the Yangtze and Cathaysia blocks. Gondwana Research, 19(1): 244–259.
- Xu, J.H., Sun, S., and Li, J.L., 1987. South China Orogen but not the South China platform. Science in China Series B-Chemistry, Life Sciences & Earth Sciences, 17(10): 1107–1115.
- Xu, B., Guo, L.Z., and Shi, Y.S., 1992. Proterozoic terrane and polyphase collision in Anhui Zhejiang Jiangxi area Mountain belt. Beijing: Geological Publishing House, 1–120.
- Zhai, M.G., and Zhou, Y.Y., 2015. General Precambrian geology in China. In: M.G. Zhai (ed.), Precambrian Geology of China, Springer Geology, 3–58.
10.1007/978-3-662-47885-1_1 Google Scholar
- Zhang, K., Wei, W.B., Lü, Q.T., and Jin, S., 2011. The study of 2-D nonlinear conjugate gradients inversion of borehole to surface magnetotelluric. Acta Geologica Sinica, 85(5): 915–924 (in Chinese with English abstract).
- Zhang, K., Dong, H., Yan, J.Y., Lu, Q.T., Wei, W.B., and He, Y.X., 2013. A NLCG inversion method of magnetotellurics with parallel structure. Chinese Journal of Geophysics, 56 (11): 3922–3931. (English edition).
- Zhang, K., Wei, W.B., and Lü, Q.T., 2014a. Four changes for efficiency and practicality on previous 3D MT NLCG inversion algorithm. Acta Geodaetica et Geophysica, 49(4): 551–563.
- Zhang, K., Wei, W.B., Lü, Q.T., Dong, H., and Li, Y.Q., 2014b. Theoretical assessment of 3-D magnetotelluric method for oil and gas exploration: Synthetic examples. Journal of Applied Geophysics, 106: 23–36.
- Zhang, K., Yan, J.Y., Lü, Q.T., Wei, W.B., Wang, H.F., and Zhang, Y.W., 2016. Correction of magnetotelluric static shift by analysis of 3D forward modeling and measured test data. Exploration Geophysics, 47(2): 100–107.
- Zhang, K., Yan, J.Y., Lü, Q.T., Zhao, J.H., and Hu, H., 2017. Three-dimensional nonlinear conjugate gradient parallel inversion with full information of marine magnetotellurics. Journal of Applied Geophysics, 139: 144–157.
- Zhang, K., Lü, Q.T., Yan, J.Y., Shao, L.S., Guo, D., and Zhang, Y.W., 2019a. The subduction and continental collision of the North China and Yangtze blocks: Magnetotelluric evidence from the Susong–Anqing section of Western Anhui, China. Geophysical Journal International, 216(3): 2114–2128.
- Zhang, K., Lü, Q.T., Yan, J.Y., Hu, H., Fu, G.M., and Luo, F., 2019b. The three-dimensional electrical structure and metallogenic prospect of the Ning (Nanjing)–Wu (Wuhu) basin and the southern adjacent area in eastern China. Journal of Asian Earth Sciences, 173(1): 304–313.
- Zhang, K., Lü, Q.T., Zhao, J.H., Yan, J.Y., Hu, H., Luo, F., Fu, G.M., and Tan, X., 2020. Magnetotelluric evidence for the multi-microcontinental composition of eastern South China and its tectonic evolution. Scientific Reports, 10: 13105.
- Zhang, K., Lü, Q.T., Lan, X.Y., Guo, D., Wang, Q.N., Yan, J.Y., and Zhao, J.H., 2021. Magnetotelluric evidence for crustal decoupling: Insights into tectonic controls on the magmatic mineral system in the Nanling–Xuancheng area, SE China. Ore Geology Reviews, 131: 104045.
- Zhang, Y.Q., and Dong, S.W., 2019. East Asia multi-plate convergence in the late Mesozoic and the development of continental tectonic systems. Journal of Geomechanics, 25(5): 613–641 (in Chinese with English abstract).
- Zhao, G.C., 2015. Jiangnan Orogen in South China: Developing from divergent double subduction. Gondwana Research, 27: 1173–1180.
- Zhao, T., Zhu, G., Lin, S.Z., and Wang, H.Q., 2016. Indentation-induced tearing of a subducting continent: Evidence from the Tan-Lu Fault Zone, East China. Earth-Science Reviews, 152: 14–36.
- Zheng, Y.F., Chen, R.X., Xu, Z., and Zhang, S.B., 2016. The transport of water in subduction zones. Science China Earth Sciences, 59(4): 651–681.
- Zhou, J.C., Wang, X.L., and Qiu, J.S., 2009. Geochronology of Neoproterozoic mafic rocks and sandstones from northeastern Guizhou, South China: Coeval arc magmatism and sedimentation. Precambrian Research, 170(2): 27–42.
- Zhou, T.F., Wang, S.W., Yuan, F., Fan, Y., Zhang, D.Y., Chang, Y.F., and White, N.C., 2016. Magmatism and related mineralization of the intra-continental porphyry deposits in the Middle-Lower Yangtze River Valley Metallogenic Belt. Acta Petrologica Sinica, 32(2): 271–288 (in Chinese with English abstract).
Citing Literature
