人才详细信息

姓名:吴 晨
性别:
学历:博士
专家类别:研究员
电话:
传真:
电子邮箱:wuchen@itpcas.ac.cn
职称:研究员
通讯地址:北京市朝阳区林萃路16号院3号楼  100101

简介

吴晨,构造地质学博士,研究员,博士生导师,主要从事基于野外构造解析的大陆构造演化与构造变形研究。

2020/04 - 至今     中国科学院青藏高原研究所,研究员

2018/01 - 2019/01  美国加州大学洛杉矶分校(UCLA),访问学者

2018/01 - 2020/04  中国地质大学(北京),副教授

2016/07 - 2017/12  中国地质大学(北京),讲师

研究方向

构造地质学

职务

社会任职

承担项目

  1. 国家自然科学基金优秀青年基金项目(2025-2027);主持
  2. 国家自然科学基金面上项目(2024-2027);主持
  3. 中国科学院率先行动青年项目择优支持(2022-2024);主持
  4. 国家自然科学基金基础科学中心子课题(2020-2024);主持
  5. 国家自然科学基金青年项目(2018-2020);主持
  6. “双一流”求真群体项目 (2018-2020);主持
  7. 中央高校基本业务费-优秀教师项目(2017-2019);主持

获奖及荣誉

2022年  第十届构造地质学与地球动力学专业委员会委员

2021年  第十三届青藏高原青年科技奖

代表论著

2024

78. Wu, C.*, Li, J., Liu, W. Y., Zuza, A.V., Haproff, P. J., Ding, L., 2024. Precambrian tectonic evolution of the Qaidam block, northern Tibet: Implications for the assembly and breakup of Proterozoic supercontinents. Earth-Science Reviews, 104985.

77. Wang, T. Y.*, He, S. L., Chen, Y. C., Aitchison, J. C., Zhang, Q. H., Li, G. B., Xi, D. P., Wu, C., Wang, L. C., Xie, J., Ding, L., 2024. Were Late Jurassic climatic fluctuations responses to Pangea breakup? Evidence from isotopic analyses of belemnite rostra from the eastern Tethyan Ocean. Geological Society of America Bulletin, in press.

76. Wu, C.*, Zhao, Y. H., Li, J., Liu, W. Y., Zuza, A. V., Haproff, P. J., Ding, L., 2024. Multicyclic Phanerozoic orogeny recorded in the Qaidam continent, northern Tibet: Implications for the tectonic evolution of the Tethyan orogenic system. Geological Society of America Bulletin, in press.

75. Lei, C., Xu, S. H.*, Zhang, W., Li, Y. H., Li, M., Wu, C., Wu, S. H., Shang, W. L., Luo, K. T., Li, X. G., Wu, K. J., Cao, Z., Xiong, Y. X., 2024. Prediction of grain shoal reservoirs via seismic forward modeling and waveform classification: Application to the northern slope of the central Sichuan Uplift, Sichuan Basin, SW China. Interpretation, in press.

74. Li, J., Wu, C.*, Li, X. G., Zuza, A. V., Haproff, P. J., Zhao, Y. H., Zhao, W. T., Yue, Y. H., Ding, L., 2024.Tectonic inversion of an intracontinental rift basin: An example from the opening and closure of the Paleo-Tethys Ocean, northern Tibetan Plateau. Geological Society of America Bulletin, 136 (11-12): 5145–5173.

73. Du, Y. S., Zhou, Z. G.*, Wang, G. S., Wu, C., Xu, W. T., 2024. Druse Calcite Crystals Formed by Mesoproterozoic Paleo-Earthquake Activity in the Northern Margin of the North China Craton. Journal of Earth Science, 35(2):514-524.

72. Wu, C.*, Huang, K.*, Yin, A., Zhang, J.Y., Zuza, A. V., Haproff, P. J., Ding, L., 2024. Tectonic geomorphology and Quaternary slip history of the Fuyun fault, southwestern Altai Mountains, Central Asia. Geosphere, 20(3):735–748.

71. Wu, C.*, Zuza, A. V., Levy, D. A., Li, J., Ding; L., 2024. Discovery of Permian–Triassic eclogite in northern Tibet establishes coeval subduction erosion along an ~3000-km-long arc: REPLY. Geology, 52 (3): e571.

70. Li, J.L.*, Liu, S.G., Ma, H.B., Wu, C., Zhu, D.C., Liu, J.G.*; 2024. Pervasive Neoarchean melting of subducted sediments generating sanukitoid and associated magmatism in the North China Craton, with implications for the operation of plate tectonics. Geological Society of America Bulletin, 136 (7-8): 3121–3136.

69. Liu, W.Y., Wu, C.*, Li, J., Zhang, C.H., Jiang, T., Zuza, A.V., Haproff, P.J., Chen, X.H., and Yue, Y.H., 2024. Structure and provenance of the Cretaceous Pingshanhu Basin in the Hexi Corridor: Implications for Mesozoic tectonics in the northern Tibetan Plateau. Geosphere, 20(2):421-450.

68. Li, L.Y., Chang, H.*, Zuza, A.V., Wu, C., Qiang, X.K., 2024. No significant provenance changes in the Hoh Xil Basin, central-northern Tibetan Plateau, from the Late Cretaceous to the Early Miocene. Global and Planetary Change, 232, 104338.

2023

67. Bai, Y.F., Shi, Z.M.*, Zhou, X.C.*, Wu, C., Wang, G.C., He, M., Li, J.C., Dong, J.Y., Tian, J., Yan, Y.C., Liu, F.L., Ouyang, S.P., Yao, B.Y., Wang, Y.W., Zeng, Z.J., Kong, X.J., 2023. Gas geochemical evidence for the India-Asia lithospheric transition boundary near the Karakorum fault in western Tibet. Chemical Geology, 639, 121728.

66. Wu, C.*, Zuza, A. V., Levy, D. A., Li, J., Ding, L., 2023. Discovery of Permian–Triassic eclogite in northern Tibet establishes coeval subduction erosion along an ~ 3000-km-long arc. Geology, 51(9): 833-838.

65. Li, J.L., Wu, C., Cheng, L., Yang, H., Zhu, D. C., Liu, J. G.*, 2023. Geodynamic controls on the Paleo-Asian oceanic plate evolution: Constraints from Paleozoic intrusive suites along the northern margin of the North China Block, Lithos, 454-455(10):107258.

64. Shang, W.L., Xu, S.H.*, Li, X.G.*, Liang, F., Wu, C., Wang, J.S., Li, Z.J., Sun, Y.H., Li, Y.H., Li, M., Xu, Z.J., Tian, Z., 2023. Utilizing 2D seismic forward modeling to constrain the seismic response and plane distribution of grain shoal reservoir in the northern slope of Central Sichuan Paleo-uplift, Sichuan Basin. Marine and Petroleum Geology, 152, 106228.

63. Li, J., Li, X.G.*, Wu, C.*, Wu, H., Haproff, P. J., Zuza, A.V., 2023. Geochronology and geochemistry of the Cryogenian sedimentary rocks and Early Paleozoic mafic dykes of the South Qinling belt: Implications for the tectonic evolution of the northwestern South China craton, Lithos, 444-445 (6):107129

62. Li, J., Wu, C.*, Chen, X. H., Zuza, A.V., Haproff, P. J., Yin, A., Shao, Z. G., 2023. Tectonic evolution of the Beishan orogen in central Asia: Subduction, accretion, and continent-continent collision during the closure of the Paleo-Asian Ocean, Geological Society of America Bulletin, 135 (3-4):819–851

61. Wu, C.*, Wang, G. S., Zhou, Z.G., Zhao, X.Q., Haproff, P. J., 2023. Late Archean–Paleoproterozoic plate tectonics along the northern margin of the North China craton, Geological Society of America Bulletin, 135 (3-4): 967–989.

60. Wu, C.*, Chen, X. H., Ding, L., 2023. Tectonic evolution and Cenozoic deformation history of the Qilian orogen. Earth Science Frontiers: 30(3): 262-281 (祁连造山带构造演化与新生代变形历史)

59. Li, X. G., Chen G., Wu, C., Li, J., Haproff, P. J., Geng, M., Wu, S. H., Xu, S. H., Li, Z. J., Yang, D., 2023. Tectono-stratigraphic framework and evolution of East Junggar Basin, Central Asia, Tectonophysics, 85: 229758.

58. Li J., Wu, C.*, Chen, X. H., Yin, A., Zuza, A. V., Haproff, P. J., Chen, Y. F., Wang, L. J., Shao, Z. G., 2023. Tectonic Setting of Metamorphism and Exhumation of Eclogite-Facies Rocks in the South Beishan Orogen, Northwestern China. Geosphere, 19(1):100-138.

57. Li, B., Wang, Y., Zuza, A. V., Chen, X., Shao, Z., Wang, Z. Z., Sun, Y. J., Wu, C., 2023. Cenozoic deformation in the eastern domain of the North Qaidam thrust belt, northern Tibetan Plateau. Geological Society of America Bulletin, 135 (1-2): 331–350.

2022

56. Wu, C.*, Wang, G. S., Zhou, Z. G., Haproff, P. J., Zuza, A. V., Liu, W. Y., 2022. Paleoproterozoic Plate Tectonics Recorded in the Northern Margin Orogen, North China Craton. Geochemistry, Geophysics, Geosystems, 23(11): e2022GC010662.

(Invited Commentary on this paper: Kusky, T. M., Traore, A., 2023. A paradigm shift: North China Craton's North Margin Orogen is the collisional suture with the Columbia Supercontinent. Geochemistry, Geophysics, Geosystems, 24, e2022GC010797).

55. He, S. L., Ding, L.*, Xiong, Z. Y., Spicer, R. A., Farnsworth, A., Valdes, P. J., Wang, C., Cai, F. L., Wang, H. Q., Zeng, D., Xie, J., Yue, Y. H., Zhao, C. Y., Song, P. P., Wu. C., 2022. A distinctive Eocene Asian monsoon and modern biodiversity resulted from the rise of eastern Tibet. Science Bulletin, 67(21):2245–2258.

54. Wu, C.*, Li, J., Zuza, A. V., Haproff, P. J., Yin, A., Ding, L., 2022. Paleoproterozoic–Paleozoic tectonic evolution of the Longshou Shan, western North China craton. Geosphere, 18(3), 1177-1193.

53. Li, J. L., Liu, J., Scott, J. M., Wu, C., Zhu, D. C., Zhang, L., 2022. Early Permian magmatism above a slab window in Inner Mongolia, North China: Implications for the Paleo-Asian Ocean subduction processes and accretionary crustal growth. Solid Earth Sciences, 7(2), 87-103.

52. Li, J. L., Liu, J., Wu, C., Zhu, D. C., Sun, S., 2022. Permian Remelting and Maturity of Continental Crust Revealed by the Daqing Peraluminous Granitic Batholith, Inner Mongolia. Lithosphere, 2022(1), 5658756.

51. Tuo, J., Wu, C.*, Wang, G., Wu, J., Zhou, Z., Li, J., Haproff, P. J., 2022. Neoproterozoic–Mesozoic Tectono-Magmatic evolution of the northern Dabie Orogen, eastern China. Journal of Asian Earth Sciences, 228, 105138.

50. Wu, C.*, Li, J., Zuza, A. V., Haproff, P. J., Chen, X., Ding, L., 2022. Proterozoic – Phanerozoic tectonic evolution of the Qilian Shan and Eastern Kunlun Range, northern Tibet. Geological Society of America Bulletin, 134 (9-10): 2179–2205.

2021

49. Wu, C.*, Li, J., Ding, L., 2021. Low-temperature thermochronology constraints on the evolution of the Eastern Kunlun Range, northern Tibetan Plateau. Geosphere, 17(4), 1193-1213.

48. Li, X. G., Xu, G. Q., Wu, C., Yin, A., Wu, S. H., Zuza, A. V., Chen, G., Li, Z. W., Xu, S. H., Li, Y. W., 2021. Pure Void Space and Fracture Pore Space in Fault-Fractured Zones. Frontiers in Earth Science, 9, 683439.

47. Wang G. S., Li H. Y., Zhou Z. G., Wu C., 2021. Tectonic significance of the newly discovered tectonic mélange within the Xingmeng orogenic belt. Chinese Journal of Geology, 56 (2), 483-507. (兴蒙造山带新发现构造混杂岩的地质意义探讨)

46. Zhou S. Y., Wu C.*, 2021, Discussion on the formation mechanism of basalt columnar joint hexagonal structure. Geological Review, 67 (6), 1629-1635. (玄武岩柱状节理六边形结构形成机制探讨)

45. Wu, C.*, Zuza, A. V., Li, J., Haproff, P. J., Yin, A., Chen, X.H., Ding, L., Li, B., 2021, Late Mesozoic–Cenozoic cooling history of the northeastern Tibetan Plateau and its foreland derived from low-temperature thermochronology. Geological Society of America Bulletin, 133 (11-12): 2393–2417.

44. Wu, C.*, Zuza, A. V., Yin, A., Chen, X., Haproff, P. J., Li, J., Li, B., Ding, L., 2021, Punctuated orogeny during the assembly of Asia: Tectonostratigraphic evolution of the North China craton and the Qilian Shan from the Paleoproterozoic to Early Paleozoic. Tectonics, e2020TC006503.

43. Wu, H., Li, X. G., Wu, C., Xia, Y., Zhou, K. K., Xiong, G. Q., Yao, X. T., 2021. Uranium and thorium elements are loss in the deep inside the Earth? Discussion from the uranium and thorium contents of zircon minerals from the Caledonian igneous plutons in the Qinling Orogen. Geological Review: 67(5), 1207-1230. (地球深部真的贫铀钍吗?-来自秦岭造山带加里东期岩浆岩体锆石铀钍含量的讨论)

42. Cheng, F., Zuza, A. V., Haproff, P. J., Wu, C., Neudorf, C., Chang, H., Li, X.Z., Li, B., 2021, Accommodation of India-Asia convergence via strike-slip faulting and block rotation in the Qilian Shan fold-thrust belt, northern margin of the Tibetan Plateau. Journal of the Geological Society. 178(3), jgs2020-207.

41. Li, J. L., Liu, J., Wang, Y., Zhu, D. C., Wu, C., 2021, Late Carboniferous to Early Permian ridge subduction identified in the southeastern Central Asian Orogenic Belt: Implications for the architecture and growth of continental crust in accretionary orogens. Lithos, 384, 105969.

40. Liu, C.F., Zhou, Z.G., Wang, G.S., Wu, C., Li, H., Ma, S., 2021, Carboniferous ridge subduction in the Xingmeng Orogenic Belt: Constraints from geochronological, geochemical, and Sr-Nd-Hf isotopic analysis of strongly peraluminous granites and gabbro-diorites in the Xilinhot micro-continent. Geoscience Frontiers, 12(3), 101103.

39. Li, B., Zuza, A. V., Chen, X., Wang, Z. Z., Shao, Z., Levy, D. A., Wu, C., Xu, S.L., Sun, Y., 2021, Pre-cenozoic evolution of the northern Qilian Orogen from zircon geochronology: Framework for early growth of the northern Tibetan Plateau. Palaeogeography, Palaeoclimatology, Palaeoecology, 562, 110091.

2020

38. Zuza, A. V., Gavillot, Y., Haproff, P. J., Wu, C., 2020, Kinematic evolution of a continental collision: Constraining the Himalayan-Tibetan orogen via bulk strain rates. Tectonophysics, 797, 228642.

37. Zhou, Z., Wu, J., Niu, Y., Wang, G., Wu, C., Liu, C., Ju, J., 2020 Geochemistry of the Mesoproterozoic Intrusions, Geochronology and Isotopic Constraints on the Xiaonanshan Cu-Ni Deposit along the Northern Margin of the North China Craton. Journal of Earth Science, 31(4), 653-667.

36. Wu, C.*, Li, J., Zuza, A. V., Liu, C., Liu, W., Chen, X., Jiang, T., Li, B., 2020, Cenozoic cooling history and fluvial terrace development of the western domain of the Eastern Kunlun Range, northern Tibet. Palaeogeography, Palaeoclimatology, Palaeoecology, 560, 109971.

35. Han, S.X., Wu, C.*, Zhou, Z. G., Wang, G. S., 2020, Geology, geochemistry, and geochronology of the Paleoproterozoic Donggouzi mafic-ultramafic complex: implications for the evolution of the North China craton. Lithos, 366-367, 105567.

34. Wu, C.*, Liu, C.F., Fan, S.Y., Zuza, A.V., Ding, L., Liu, W.C., Ye, B.Y., Yang, S.J., Zhou, Z.G., 2020, Structural analysis and tectonic evolution of the western domain of the Eastern Kunlun Range, northwest Tibet. Geological Society of America Bulletin, 132 (5-6), 1291-1315.

2019

33. Wu, C.*, Zuza, A. V., Chen, X., Ding, L., Levy, D. A., Liu, C., Liu, W., Jiang, T., and Stockli, D. F., 2019, Tectonics of the Eastern Kunlun Range: Cenozoic reactivation of a Paleozoic-early Mesozoic orogen. Tectonics, 38, 1609–1650.

32. Wu, C.*, Zuza, A. V., Zhou, Z., Yin, A., McRivette, M., Chen, X., Ding, L., and Geng, J., 2019, Mesozoic-Cenozoic evolution of the Eastern Kunlun Range, central Tibet, and implications for basin evolution within the Indo-Asian collision. Lithosphere, 11 (4), 524-550.

31. Song, Z. J., Zhang, H. Y., Hou, D., Liu, C. F., Liu, W. C., Wu, C., 2019, Discovery and the geological significance of retrograded eclogites from the northern margin of the central Qilian block. Earth Science Frontiers, 26 (2), 233-248. (中祁连地块北缘退变榴辉岩的发现及其地质意义)

30. Song, Z. J., Liu, W. C., Zhang, H. Y., Liu, C. F., Luo, K., Wu. C., 2019, Detrital zircon geochronology and its geological significance of Upper Permian sandstones in Yushigou area of western Qilian Mountains, China. Geoscience, 33 (1), 112-120. (祁连山西段玉石沟地区上二叠统砂岩碎屑锆石年代学及其地质意义

29. Haproff, P. J., Zuza, A. V., Yin, A., Harrison, T. M., Manning, C. M., Ding, L., Wu, C., Chen, J., and Dubey, C. S., 2019, Tectonic evolution of the northern Indo-Burma Ranges (Part 1): lateral correlation of Himalayan-Tibetan lithologic units across the eastern Himalayan syntaxis. Geosphere, 15 (3), 856-881.

28. Liu C.F., Wu, C., Song, Z.J., Liu, W.C., Zhang, H.Y., 2019, Petrogenesis and tectonic significance of Early Paleozoic magmatism in the northern margin of the Qilian block, northeastern Tibetan Plateau. Lithosphere, 11 (3), 365-385.

27. Zuza, A. V., Wu, C., Wang, Z., Levy, D. A., Li, B., Xiong, X., and Chen, X, 2019, Underthrusting and duplexing beneath the northern Tibetan Plateau and the evolution of the Himalayan-Tibetan orogen. Lithosphere, 11 (2), 209-231.

26. Li, J. L., Zhou, Z. G., Wu, C., Wang, Y., Wang, G. S., Liu, C. F., Wu, J., 2019, Geochronology, petrogenesis, and tectonic implications of the Early Permian volcanic rocks in the northern margin of the North China craton. Geological Journal, 54 (3), 1535-1553.

25. Wang, G. S., Zhou, Z. G., Liu, C. F., Wu, C., Li, H., Jiang, T., 2019, Tectonic significance of the Late Carboniferous Zhunmubutai ophiolitic mélange from Xi‐Ujimqin, Inner Mongolia. Geological Journal, 54 (1), 364-377.

24. Zhou, Z. G., Liu, C. F., Wang, G., Zhang, N., Li, H., Wu, C., 2019, Geochronology, geochemistry and tectonic significance of the Dashizhai ophiolitic mélange belt, southeastern Xing’an–Mongolia orogenic belt. International Journal of Earth Sciences, 108 (1), 67-88.

2018

23. Wu, C.*, Zhou, Z., Zuza, A. V., Wang, G., Liu, C., and Jiang, T., 2018, A 1.9‐Ga Mélange Along the Northern Margin of the North China Craton: Implications for the Assembly of Columbia Supercontinent. Tectonics, 37 (10), 3610-3646.

22. Liu, C. F., Xu, M. T., Zhou, Z. G., Wang, G. S., Wu, C., Zhu, Y., Li, H., Ye, B. Y., 2018, Magmatic history during late Carboniferous to early Permian in the North of the central Xing’an-Mongolia Orogenic Belt: a case study of the Houtoumiao pluton, Inner Mongolia. International Geology Review, 60 (15), 1918-1939.

21. Zhou, Z. G., Wang, G. S., Di, Y. J., Gu, Y. C., Zhang, D., Zhu, W. P., Wu, C., Chen, L. Z. 2018, Discovery of Mesoproterozoic kimberlite from Dorbed Banner, Inner Mongolia and its tectonic significance. Geological Journal, 53 (3), 992-1004.

20. Liu, C. F., Zhou, Z. G., Wang, G., Wu, C., Li, H., Zhu, Y., Ye, B. 2018, Geochronology and geochemistry of the Late Jurassic bimodal volcanic rocks from Hailisen area, central‐southern Great Xing'an Range, Northeast China. Geological Journal, 53 (5), 2099-2117

19. Li, J. L., Zhou, Z. G., He, Y., Wang, G. S., Wu, C., Liu, C. F., Dai, P., 2018, Geochronological and sedimentological evidences of Panyangshan foreland basin for tectonic control on the Late Paleozoic plate marginal orogenic belt along the northern margin of the North China Craton. International Journal of Earth Sciences, 107 (4), 1193-1213.

18. Wang, G.S, Liu, C.F, Pei, W.X., Zhou, Z.G., Li, H.Y., Wu C., Zhu Y., Ye B.Y., 2018, Geochemistry and zircon U–Pb–Hf isotopes of the granitoids of Qianjinchang pluton in the Xi Ujimqi, Inner Mongolia: implications for petrogenesis and geodynamic setting. Geological Journal, 53, 767-787.

17. Zhou, Z. G., Hu, M., Wu, C., Wang, G., Liu, C., Cai, A., Jiang, T., 2018, Coupled U–Pb dating and Hf isotopic analysis of detrital zircons from Bayan Obo Group in Inner Mongolia: Constraints on the evolution of the Bayan Obo rift belt. Geological Journal, 53 (6), 2649-2664.

16. Liu, C. F., Wu, C.*, Zhou Z. G, Zhu Y., Jiang T., Song Z. J., Liu W. C., Yang X., Zhang H. Y., 2018, U–Pb detrital zircon geochronology from the basement of the Central Qilian Terrane: implications for tectonic evolution of northeastern Tibetan Plateau. International Journal of Earth Sciences, 107 (2), 673-686.

15. Zuza, A. V., Wu, C., Reith, R. C., Yin, A., Li, J., Zhang, J., Zhang, Y., Wu, L., and Liu, W., 2018, Tectonic evolution of the Qilian Shan: A Paleozoic orogen reactivated in the Cenozoic. Geological Society of America Bulletin, 130 (5-6), 881-925.

2017

14. Wu, C.*, Wang, G. S., Zhou, Z. G., Liu, C. F., Liu, W. C., Jiang, T., 2017, Constrasts and enlightenments from field capacity trained of Geological students by regional geological mapping between China and America. Chinese Geological education, 26 (4), 94-97. (中美通过区域地质填图培养地质专业大学生野外能力的对比与启示)

13. Wang, G. S., Wu, C., Chen, C., Zhou, Z. G., Liu, C. F., Jiang, T., 2017, Geochronological data of igneous and metamorphic rocks from the Xing’an-Mongolia Orogenic Belt of the eastern Central Asian Orogenic Belt: implications for the final closure of the Paleo-Asian Ocean. International Journal of Earth Sciences, 106 (8), 2727-2746.

12. Liu, C. F., Zhou, Z. G., Tang, Y., Wu, C., Li, H., Zhu, Y., Ye, B. Y., 2017, Geochronology and tectonic settings of Late Jurassic–Early Cretaceous intrusive rocks in the Ulanhot region, central and southern Da Xingan Range. Geological Magazine, 154 (5), 923-945.

11. Liu, C. F., Zhou, Z. G., Wu, J., Li, H., Wu, C., Zhu, Y., Ye, B. Y., 2017, Geochronology, geochemistry and tectonic implications of Weitingchagan composite pluton in northern segment of the Xing‐Meng Orogenic Belt. Geological Journal, 52 (6), 900-918.

10. Li, H.S., Wu, C.*, Luo, T.W., Jiang, T., Chen, Y.F., Wang, G.H., 2017, Ages and geochemistry of the Renacuo granitoids in the Gaize area, central Tibet: Implications for the northward subduction of the Bangong Suture Ocean. Geological Journal, 52 (1), 14-29.

9. Wu, C.*, Zuza, A. V., Yin, A., Liu, C., Reith, R. C., Zhang, J., Liu, W. C., Zhou, Z. G., 2017, Geochronology and geochemistry of Neoproterozoic granitoids in the central Qilian Shan of northern Tibet: Reconstructing the Amalgamation Processes and Tectonic History of Asia. Lithosphere, 9 (4), 609-636.

8. Wu, C.*, Wang, B., Zhou, Z., Wang, G., Zuza, A. V., Liu, C., Jiang, T., Liu, W., Ma, S., 2017, The relationship between magma and mineralization in Chaobuleng iron polymetallic deposit, Inner Mongolia. Gondwana Research, 45, 228-253.

2016

7. Wang, X. B., Ge, J. P., Wei, W., Li, H., Wu, C., Zhu, G., 2016, Spatial dynamics of the communities and the role of major countries in the international rare earths trade: a complex network analysis. PloS one, 11(5)

6. Wu, C., Yin, A.*, Zuza, A. V., Zhang, J., Liu, W., Ding, L., 2016, Pre-Cenozoic Geologic History of the Central and Northern Tibetan Plateau and the Role of Wilson Cycles in Constructing the Tethyan Orogenic System. Lithosphere, 8 (3), 254-292

5. Wu, C.*, Liu, C. F., Zhu, Y., Zhou, Z. G., Jiang, T., Liu, W. C., Li, H. Y., Wu, C., Ye, B.Y., 2016, Early Paleozoic magmatic history of central Inner Mongolia, China: implications for the tectonic evolution of the Southeast Central Asian Orogenic Belt. International Journal of Earth Sciences, 105 (5), 1307-1327

4. Wu C.*, Jiang T., Wu C., Li H.S., Li Z., Liu W.C., 2016, Geochemistry, zircon U-Pb and molybdenite Re-Os dating of the Taolaituo porphyry Mo deposit in the Central Great Hinggan Range: implications for the geodynamic evolution of northeastern China. Geological Journal, 51(6), 949-964

2015-2013

3. Wu C.*, Jiang T., Liu W. C., Zhang D., Zhou Z. G., 2015, Early Cretaceous adakitic granites and mineralization of the Yili porphyry Mo deposit in the Great Xing'an Range: implications for the geodynamic evolution of northeastern China. International Geology Review, 57 (9-10), 1152-1171

2. Wu C.*, Jiang T., Liu C. F., Liu W. C., 2014, Early Cretaceous A-type granites and Mo mineralization, Aershan area, eastern Inner Mongolia, Northeast China: geochemical and isotopic constraints. International Geology Review, 56 (11), 1357-1376

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