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Zhang, E.H
Zhang, E.H
Published on 2024-12-14 / 94 Visits
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2024

  1. Xue, E.-K†., Chew, D., Drakou, F. and Wang, W*., 2024. Detrital multi-mineral provenance constraints on the reconstruction of the South China Block within Gondwana. Earth-Science Reviews: 104798.

  2. Zhang, J†., Li, R., Pandit, M.K., Lan, T.-G., Xiong, Q., Wu, Y.-B., Zhao, J.-H. and Wang, W*., 2024. Quartz trace element geochemistry and internal morphology as proxies for provenance characterization: Results from the Marwar basin, NW India. Precambrian Research, 409: 107436.

  3. 王伟*,薛尔堃†,张杨†,章俊†,蔡欣豫†,华夏陆块晚新元古代-早古生代沉积物源的组成与演化及其对冈瓦纳大陆重建的意义. 华南地质

  4. Lu, G.M†., Xu, Y.G*., Wang, W*., Spencer, C.J., Huang, G. and Roberts, N.M., 2024. Continental crust rejuvenation across the Paleo‐Mesoarchean transition resulted from elevated mantle geotherms. Geophysical Research Letters, 51(8): e2024GL108715.

  5. Xue E.K†., Zhao J.H., Chew D., Pandit M.K., Deng X., Tian Y., Tong X.R., Wang, W*., 2024. Record from early Paleozoic migmatites in South China: episodic water-fluxed anatexis in intraplate orogeny during Gondwana assembly. Gondwana Research, 126, 96-11,https://doi.org/10.1016/j.gr.2023.09.011

  6. Xue E.K†., Chew D., Drakou F., Wang, W*., 2024. Paleographical reconstruction of the South China Block during the Gondwana assembly using detrital apatite: Pan-African source affinity concealed by detrital zircon. Geological Society of America Bulletin,136 (5-6): 2063–2074,https://doi.org/10.1130/B36988.1

  7. Tian, Y., Xue, E*., Wang, W*., Niu, Z., Tu, B., Wang, L., Wang, Z., Song, F., He, Y., 2024. Northwestward migration of siliciclastic sedimentation during late Tonian to Cambrian: Implications for tectonic evolution of the South China Block. Precambrian Research 403, 107311.

  8. 汪子祺, 田洋*, 金巍, 邓新, 王晶, 童喜润, 柳潇, 2024. 大别地区构造与地壳演化——来自河流碎屑锆石U-Pb-Hf同位素的制约. 沉积学报 23, 185-220.

2023

  1. Huang, B†., Wang, W*., Zhao, J.-H., Khattak, N.U., Huang, S.F†., Lu, G.M†., Xue, E.K†., Sun, L†., 2023. Coupled alkaline high-Nb mafic rocks and adakitic granodiorites: Products of Neoproterozoic back-arc extension at the western margin of the Yangtze Block, South China. Geological Society of America Bulletin. 136 (1-2): 637–660, https://doi.org/10.1130/B36618.1

  2. Yomeun, B. S†., Wang. W*, J. P. Tchouankoue, M. S. K. Kamani†, K. I. A. Ndonfack and E. A. A. Basua 2023. Microstructural constraints on the Pan-African syn-kinematic magmatism in the Adamawa-Yade domain, Cameroon. Arabian Journal of Geosciences 16(10): 567,https://doi.org/10.1007/s12517-023-11667-9

  3. Lu G.M†., Cawood P. A., Spencer Chrisopher., Bekker Andrey., Xu Y.G., Yao Z.S.,Wang, W*., 2023., Contrasting topography of Rodinia and Gondwana recorded by continental-arc basalts. Lithos, 107094, https://doi.org/10.1016/j.lithos.2023.107094

  4. Lu G.M†., Wang, W*., Ernst R.E., El Bilali H., Spencer C.J., Xu Y.G., Bekker A., 2023., Evolutionary stasis during the Mesoproterozoic Columbia-Rodinia supercontinent transition. Precambrian Research 391, 107057, https://doi.org/10.1016/j.precamres.2018.12.019

  5. Wang, W*., Chris Spencer., Pandit, Manoj., Wu, Yuanbao., Zhao, Junhong., Zheng, Jianping., Xia Xiaoping., Lu, Guimei†. 2023., Crustal evolution and tectonomagmatic history of the Indian Shield at the periphery of supercontinents. Geochimica Cosmochimica Acta, 341, 90-104,http://doi.10.1016/j.gca.2022.10.040

2022

  1. 王伟*,2022. 全球尺度上大陆地壳抬升的时间、机制与效应是什么?地球科学,47,10,1-2. https://doi.org/10.3799/dqkx.2022.813

  2. Zhao, J.H., Yang, T., Wang, W., 2022. Orogenic belt resulting from ocean-continent collision. Geology.

  3. Khattaka, Nimat.U., Zhu, Yuxiang, Ma, Changqian., Wang, Lianxun., Wang W. 2022. Recognition of the Emplacement Time of the Sillai Patti Carbonatite Complex, Malakand Division, North West Pakistan: Constraints from 206Pb/238U dating of Zircon. Pakistan Journal of Geology,

  4. Sun, Li†., Wang, W*, Pandit, Manoj., Lu, Guimei†., Xue, Erkun†, Huang, Bin†., Zhang, Yang†., Jin, Wei., Tian, Yang†. 2022., Geochemical and detrital zircon age constraints on Meso- to Neoproterozoic sedimentary basins in the southern Yangtze Block: implications on Neoproterozoic geodynamics of South China and Rodinia configuration, Precambrian Research, 378, 106779, https://www.sciencedirect.com/science/article/pii/S0301926822002236

  5. Yomeun, Bovari Syprien†., Wang,W*. Kamguia Kamani, Michele Sandra†., Tchouankoue Jean Pierre., Ndonfack, Kevin Igor Azeuda., Huang, Si.Fang†., Afanga Basua, Emmanuel Archelaus., Lu, Gui-Mei†., Xue, Er-Kun†., 2022. Petrogenesis and tectonic implication of Neoproterozoic I-Type Granitoids and orthogneisses in the Goa-Mandja area, Central African Fold Belt (Cameroon), Lithos, 420-421, 106700, https://doi.org/10.1016/j.lithos.2022.106700

  6. Yomeun, Bovari Syprien†., Wang,W*. Kamguia Kamani, Michele Sandra†., Tchouankoue Jean Pierre., Jiang, Ying-De., Huang, Si-Fang†., Ndonfack, Kevin Igor Azeuda., Xue, Er-Kun†., Lu, Gui-Mei†., Afanga Basua, Emmanuel Archelaus. 2022, Geochronology, geochemistry and Sr-Nd, Hf-O isotope systematics of the Linte massif, Adamawa - Yade domain, Cameroon: implications on the evolution of the Central African Fold Belt, Precambrian Research, 375, 106675, https://doi.org/10.1016/j.precamres.2022.106675

  7. Tian, Y., Wang, W*., Jin,W., Wu, Y.B., Wang, J., Deng, X., Huang, S.F., 2022, Neoarchean granitic rocks from the Jiamiao area of the Northern Dabie Orogen: implications on the formation and early evolution of the Yangtze Craton, Science China Earth Sciences, 65, https://doi.org/10.1007/s11430-021-9935-5

  8. 田洋, 王伟*, 金巍, 吴元保, 王晶, 邓新, 黄思访,2022,北大别贾庙新太古代花岗质岩石:对扬子克拉通形成与演化的制约,中国科学:地球科学,52: 1–20, doi: 10.1360/SSTe-2021-0369

  9. Zhang, Jun†., Pandit, Manoj K., Chen, Terry Wei., Wang, Wei*, 2022, Middle Neoproterozoic - early Cambrian sedimentation in NW India: implications on the transition from Rodinia to Gondwana, Journal of Asian Earth Sciences, 229, 105171

  10. Lu, G.M†., Spencer, C., Deng, X., Tian, Y†., Huang, Bin†., Jiang, Ying-De., Wang, W*, 2022, Mesoproterozoic magmatism redefines the tectonics and paleogeography of the SW Yangtze Block, China, Precambrian Research, 370, 106558  

  11. Wang, W*., Cawood, P. A., Spencer Chrisopher, Pandit M.K, Zhao J.H., Xia, X.P., Zheng, J.P., Lu G.M†., 2022, Global-scale emergence of continental crust during the Mesoarchean and early Neoarchean, Geology, 50(2), 184-188, https://doi.org/10.1130/G49418.1

2021

  1. Mollai, H., Dabiri, R., Torshizian, H. A., Pe-Piper, G., and Wang, W, 2021. Upper Neoproterozoic garnet-bearing granites in the Zeber-Kuh region from east central Iran micro plate: Implications for the magmatic evolution in the northern margin of Gondwanaland, Geologica Carpathica, 72, 6, 461-481

  2. Wang, W*., Cawood, P. A., Spencer Chrisopher, Pandit M.K, Zhao J.H., Xia, X.P., Zheng, J.P., Lu G.M., 2021, Global-scale emergence of continental crust during the Mesoarchean and early Neoarchean, Geology, https://doi.org/10.1130/G49418.1

  3. Zhao, Jun-Hong*, Wang, Wei*., 2021, Precambrian tectonothermal events and crustal evolution of South China: an introduction, Journal of Asian Earth Sciences, 104935

  4. Huang, S.F†, Wang, W*., Kerr, A.C., Zhao, J.H., Xiong, Q., 2021, The Fuchuan Ophiolite in South China: Evidence for modern-style plate tectonics during Rodinia breakup, Geochemistry, Geophysics, Geosystems, 22, e2021GC010137

  5. Lu, G.M†., Spencer, C., Tian, Y., Wang, W*., 2021, Significant increase of continental freeboard during the early Paleoproterozoic: Insights from sediment-derived granites, Geophysical Research Letters, 48, e2021GL096049.

  6. Sun Li†., Wang, W*., Lu, G†., Xue, E†., Huang, S†., Pandit, M.K., Huang, B†., Tong, X., Tian, Y†., Zhang, Y†., 2021. Neoproterozoic geodynamics of South China and implications on the Rodinia configuration: the Kunyang Group revisited, Precambrian Research, 363, 106338.

  7. Lu, G.M†., Wang, W*., Tian, Y†., Spencer, C.J., Huang, S.F†., Xue, E.K†., Huang, B†., 2021. Siderian mafic-intermediate magmatism in the SW Yangtze Block, South China: Implications for global ‘tectono-magmatic lull’ during the early Paleoproterozoic. Lithos 398-399, 106306

  8. Liu, Z.R.R., Zhou, M.F., Wang, W., 2021. Mercury anomalies across the Ediacaran–Cambrian boundary: Evidence for a causal link between continental erosion and biological evolution. Geochimica et Cosmochimica Acta 304, 327-346

  9. Pandit, M. K., Kumar, H., and Wang, W., 2021,Geochemistry and geochronology of A-type basement granitoids in the north-central Aravalli Craton: Implications on Paleoproterozoic geodynamics of NW Indian Block: Geoscience Frontiers, v. 12, p. 101084.

  10. Kamguia Kamani M.S†., Wang , W*., Tchouankoue J.-P, Huang, S.F†., B Yomeun†, Xue, E.K†., Lu, G.M†., 2021 Neoproterozoic syn-collision magmatism in the Nkondjock region at the Northern border of the Congo Craton in Cameroon: Geodynamic implications for the Central African Orogenic belt, Precambrian Research, 353, 106015

  11. Wang, W*., Cawood, P. A., Manoj P.K., Xia, X.P., Raveggi, M., Zhao J.H., Zheng, J.P., Qi, L. 2020. Fragmentation of South China from greater India during the Rodinia-Gondwana transition. Geology, 49, 228-232

  12. Xue, E.K†., Wang, W*., Zhou, M.F., Pandit, M.K., Huang, S.F†., Lu, G.M†., 2021, Late Neoproterozoic-early Paleozoic basin evolution in the Cathaysia Block, South China: Implications of spatio-temporal provenance changes on the paleogeographic reconstructions in supercontinent cycles: GSA Bulletin, 133(3/4),717-739

  13. Wang, W*., Cawood, P. A., Manoj P.K., 2021. India in the Nuna to Gondwana supercontinent cycles: Clues from the North India and Marwar Blocks. American Journal of Science, 321, 83-117

  14. Liu, G.C., Li, J., Qian, X., Feng, Q.L., Wang, W., Chen, G.Y., Hu, S.B., 2021, Geochronological and geochemical constraints on the petrogenesis of late Mesoproterozoic mafic and granitic rocks in the southwestern Yangtze Block. Geoscience Frontiers, 12, 39-52

2020

  1. Zhu, Y.X., Wang, L.X., Ma, C.Q., Wiedenbeck, M., and Wang, W., 2020, The Neoproterozoic alkaline rocks from Fangcheng area, East Qinling (China) and their implications for regional Nb mineralization and tectonic evolution: Precambrian Research, p. 105852.

  2. Pang, L.Y., Zhu, X.Y., Hu, B., Wang, W., Sun, Q.Y., and Zhao, T.P., 2020, Detrital zircon U-Pb age and Hf isotopic composition and whole-rock geochemical characteristics of the Statherian Huangqikou Formation, western margin of the North China Craton: Implications for provenance and tectonic evolution: Precambrian Research, 347, 105840.

  3. Tian, Y†., Wang , W*., Wang, L.Z*., Li, X., Xie, G.G., Huang, S.F†., 2020. Age and petrogenesis of the Yingyangguan volcanic rocks: implications on constraining the boundary between Yangtze and Cathaysia blocks, South China. Lithos,376-377,105775

  4. Lu, G†., Wang, W*., Cawood, P. A., Ernst, R.E., Raveggi, Massimo., Huang, S.F†., Xue, E.K†., 2020, Late Paleo- to early Mesoproterozoic mafic magmatism in the SW Yangtze Block: Mantle plumes associated with Nuna breakup? Journal of Geophysical Research: Solid Earth, 125, 7, doi: 10.1029/2019JB019260

  5. Cawood, P. A., Wang, W., Zhao, T., Xu, Y., Mulder, J. A., Pisarevsky, S. A., Zhang, L., Gan, C., He, H., Liu, H., Qi, L., Wang, Y., Yao, J., Zhao, G., Zhou, M.-F., and Zi, J.-W., 2020, Deconstructing South China and consequences for reconstructing Nuna and Rodinia: Earth-Science Reviews, p. 103169.

2019

  1. Mollai, H., Dabiri, R., Torshizian, H. A., Pe-Piper, G., and Wang, W., 2019, Cadomian crust of Eastern Iran: evidence from the Tapeh Tagh granitic gneisses: International Geology Review, p. 1-21. doi. 10.1080/00206814.2019.1670100.

  2. Zhao, J.H., Zhou, M.F., Wu, Y.B., Zheng, J.P., and Wang, W., 2019, Coupled evolution of Neoproterozoic arc mafic magmatism and mantle wedge in the western margin of the South China Craton: Contributions to Mineralogy and Petrology, v. 174, no. 4, p. 36, doi. 10.1007/s00410-019-1573-7.

  3. Xue, E.-K†., Wang, W*., Huang, S.-F†., Lu, G.-M†., 2019. Detrital zircon U-Pb-Hf isotopes and whole-rock geochemistry of neoproterozoic-cambrian successions in the Cathaysia Block of South China: Implications on paleogeographic reconstruction in supercontinent. Precambrian Research 331, 105348.

  4. Huang S.F†., Wang, W*., Manoj Pandit, Zhao J.H., Lu G.M†., Xue E.K†., 2019. Neoproterozoic S-type granites in the western Jiangnan Orogenic Belt,South China: Implications for petrogenesis and geodynamic significance. Lithos, 342-343, 45-58

  5. Liu K†., Lu G.M†., Wang Z.Z., Huang S.F†., Xue E.K†., Wang, W*., 2019. The Paleoproterozoic bimodal magmatism in the SW Yangtze Block: Implications for initial breakup of the Columbia supercontinent. Lithos, 332-333, 23-38

  6. Liu, Z.-R.R., Zhou, M.-F., Williams-Jones, A.E., Wang, W., Gao, J.-F., 2019. Diagenetic mobilization of Ti and formation of brookite/anatase in early Cambrian black shales, South China. Chemical Geology. In press: 10.1016/j.chemgeo.2018.12.022

  7. Cui, X.Z., Wang, J., Sun, Z.M., Wang, W., Deng, Q., Ren, G.M., Liao, S.Y., Huang, M.D., Chen, F.L., 2019. Early Paleoproterozoic (ca. 2.36 Ga) granitic magmatism in post –collisional setting: implication of the Yangtze Block of South China in the Columbia supercontinent. Journal of Asian Earth Sciences. 169, 308-322

  8. Li, Q.W., Zhao, J.H., Wang, W., 2019. Ca. 2.0 Ga mafic dikes in the Kongling Complex, South China: Implications for the reconstruction of Columbia. Journal of Asian Earth Sciences, 169, 323-335.

  9. Lu, G†., Wang, W*., Ernst, R.E., Söderlund, U., Lan, Z†., Huang, S†., Xue, E†., 2019. Petrogenesis of Paleo-Mesoproterozoic mafic rocks in the southwestern Yangtze Block of South China: Implications for tectonic evolution and paleogeographic reconstruction. Precambrian Research, 322, 66-84

  10. Huang S.F†., Wang W*., 2019. The origin of the Fanjingshan mafic-ultramafic rocks, western Jiangnan Orogen, South China: implications for PGE fractionation and mineralization. Journal of Earth Science. 30, 258-271

  11. Wang, W*., Cawood, P.A., Pandit M.K., Zhao J.H., Zheng J.P. 2019. No Collision between Eastern and Western Gondwana at their northern extent. Geology, 47, 308-312

  12. Wang, W*., Cawood, P.A., Pandit M.K., Zhou M.F., Zhao J.H., 2019. Evolving passive- and active- margin tectonics of the Paleoproterozoic Aravalli Basin, NW India. Geological Society of American Bulletin, 131, 3/4, 426-443

  13. 王伟,卢桂梅,黄思访,薛尔堃, 2019. 扬子陆块古-中元古代地质演化与Columbia超大陆重建. 矿物岩石地球化学通报, 第38卷,第1期,30-52页。(侯德封获奖者论文)

  14. Huang S.F†., Wang W*., 2019. The origin of the Fanjingshan mafic-ultramafic rocks, western Jiangnan Orogen, South China: implications for PGE fractionation and mineralization. Journal of Earth Science. In press, doi: 10.1007/s12583-018-0984-0

  15. Qi, L., Xu, Y.J., Cawood, P.A., Wang, W., Du, Y.S., 2019. Implications of 770 Ma Rhyolitic Tuffs, eastern South China Craton in constraining the tectonic setting of the Nanhua Basin. Lithos, 324-325, 842-858

2018

  1. Xiang, L., Zheng, J.P., Siebel, W., Griffin, W., Wang, W., O'Reilly, S., Li, Y.H., Zhang, H., 2018. Unexposed Archean components and complex post-Archean accretion/reworking processes beneath the southern Yangtze Block revealed by zircon xenocrysts from Paleozoic lamproites, South China. Precambrian Research, 316, 174-196

  2. Huang, S.F†., Wang, W*., Zhao, J.H., Zheng, J.P., 2018. A-type magmatism in post-collisional setting: petrogenesis and geodynamic significance of the ~ 850 Ma Dongling granitoids in South China, Lithos, 318-319, 176-193

  3. Zhao, J.H., Pandit, M.K., Wang, W., Xia, X.P., 2018. Neoproterozoic tectonothermal evolution of NW India: Evidence from geochemistry and geochronology of granitoids. Lithos, 316-317, 330-346

  4. Wang, W*., Cawood, P.A., Pandit M.K., Xia X.P., Zhao J.H., 2018. Coupled crustal evolution and supercontinent cycle: insights from in situ U-Pb, O and Hf isotopes in detrital zircon, NW India, American Journal of Science, 318, 989-1017

  5. Guo, J.W, Zheng J.P., Ping, X.Q., Wan Y.S., Li, Y.H, Wu, Y.B, Zhao, J.H, Wang, W., 2018. Paleoproterozoic porphyries and coarse-grained granites manifesting a vertical hierarchical structure of Archean continental crust beneath the Yangtze Craton Precambrian Research 318, 288-305

  6. Liu H, Zhao, J.H, Cawood, P.A, Wang, W., 2018. South China in Rodinia: Constrains from the Neoproterozoic Suixan volcano-sedimentary group of South Qinling Belt. Precambrian Research 314, 170-193

  7. Wang, W*., Bolhar, R., Zhou, M.-F., Zhao, X.-F., 2018. Enhanced terrestrial input into Paleoproterozoic to Mesoproterozoic carbonates in the southwestern South China Block during the fragmentation of the Columbia supercontinent. Precambrian Research 313, 1-17.

  8. Luo, B.J., Liu, R., Zhang, H.F., Zhao, J.H., Yang, H., Xu, W.C., Guo, L., Zhang, L.Q., Tao, L., Pan, F.B., Wang, W., Zhong, G., Hui, S., 2018. Neoproterozoic continental back-arc rift development in the Northwestern Yangtze Block: Evidence from the Hannan intrusive magmatism. Gondwana Research 59, 27-42

  9. de Wall, H., Pandit, M.K., Donhauser, I., Schöbel, S., Wang, W., Sharma, K.K., 2018. Evolution and tectonic setting of the Malani – Nagarparkar Igneous Suite: A Neoproterozoic Silicic-dominated Large Igneous Province in NW India-SE Pakistan. Journal of Asian Earth Sciences 160, 136-158.

  10. Wang, W*., Zeng, M.-F., Zhou, M.-F., Zhao, J.-H., Zheng, J.-P., Lan, Z.-F., 2018. Age, provenance and tectonic setting of Neoproterozoic to early Paleozoic sequences in southeastern South China Block: Constraints on its linkage to western Australia-East Antarctica. Precambrian Research. 309, 290-308.

  11. Chen, W.T., Sun, W.H., Zhou, M.F., Wang, W., 2018. Ca. 1050 Ma intra-continental rift-related A-type felsic rocks in the southwestern Yangtze Block, South China. Precambrian Research. 309, 22-24.

  12. Wang, W*., Pandit, M.K., Zhao, J.-H., Chen, W.-T., Zheng, J.-P., 2018. Slab break-off triggered lithosphere - asthenosphere interaction at a convergent margin: The Neoproterozoic bimodal magmatism in NW India. Lithos 296-299, 281-296.

  13. Wang, W*., Zhao, J.H., Zhou, M., Pandit, M.K., Zheng, J.P., 2018. Depositional age, provenance and tectonic setting of the Meso- and Neoproterozoic sequences in SE Yangtze Block, China: Implications on Proterozoic supercontinent reconstructions. Precambrian Research. 309, 231-247

2017

  1. Wang, W*., Cawood, P.A., Zhou, M.F., Pandit, M.K., Xia, X.P., Zhao, J.H., 2017. Low-δ18O rhyolites from the Malani Igneous Suite: a positive test for South China and NW India linkage in Rodinia. Geophysical Research Letters 44, 10298-10305.

  2. Wang, W*., Cawood, P.A., Zhou, M.F., Pandit, M.K., Chen, W.T., 2017. Zircon U-Pb age and Hf isotope evidence for Eoarchean crustal remnant, and crustal growth and reworking respond to supercontinental cycles in NW India. Journal of Geological Society 174, 759-772.

  3. Sun, Q.Y, Zhou, Y.Y, Wang, W., Li, C., Zhao, T.P, 2017. Formation and evolution of the Paleoproterozoic meta-mafic and associated supracrustal rocks from the Lushan Taihua Complex, southern North China Craton: Insights from zircon U-Pb geochronology and whole-rock geochemistry. Precambrian Research 303, 428-444.

  4. Sun, Q.Y, Zhou, Y.Y, Zhao, T.P, Wang, W., 2017. Geochronology and geochemistry of the Paleoproterozoic Yinyugou Group in the southern North China Craton: Implications for provenance and tectonic evolution. Precambrian Research 296, 120-147.

  5. Cawood, P.A., Zhao, G.C., Yao, J.L., Wang, W., Xu, Y.J., Wang, Y.J., 2017. Reconstructing South China in Phanerozoic and Precambrian supercontinents. Earth Science Reviews.

2016

  1. Hu, R., Wang, W*., Li, S.Q., Yang, Y.Z., Chen, F.K., 2016. Sedimentary environment of Ediacaran sequences of South China: trace element and Sr-Nd isotope constraints. The Journal of Geology 124, 769–789. (corresponding autho)

  2. Wang, W*., Zhou, M.-F., Zhao, J.-H., Pandit, M., Zheng, J.-P., Liu, Z.-R., 2016. Neoproterozoic active continental margin in the southeastern Yangtze Block of South China: evidence from the ca. 830-810 Ma sedimentary strata. Sedimentary Geology 342, 254-267.

  3. Wang, W*., Cawood, P.A., Zhou, M.-F. and Zhao, J.-H. 2016. Paleoproterozoic magmatic and metamorphic events link Yangtze to northwest Laurentia in the Nuna supercontinent. Earth and Planetary Science Letters 433, 269-279.

  4. Li, Y.H., Zheng, J.P., Xiong, Q., Wang, W., Ping, X.Q., Li, X.Y., Tang, H.Y., 2016. Petrogenesis and tectonic implications of Paleoproterozoic metapelitic rocks in the Archean Kongling Complex from the northern Yangtze Craton, South China. Precambrian Research 276, 158-177.

  5. 胡蓉,李双庆,王伟,陈福坤,2016扬子北部三峡地区南沱组冰碛 岩的物源特征:锆石年龄和地球化学证据,地球科学,.(10):1630~1654

2015及以前

  1. 赵军红,王伟,刘航,2015. 扬子东南缘新元古代地质演化,矿物岩石地球化学通报,113(10):3631~3637

  2. Wang W, Zhou M-F, Zhao X-F, Chen W-T. 2014. Late Paleoproterozoic to Mesoproterozoic rift successions in SW China: implication for the Yangtze Block-North Australia-Northwest Laurentia connection in the Columbia supercontinent. Sedimentary Geology, 309, 33-47

  3. Wang W., Zhao J.H., Zhou M-F., Yang S.H., Chen F.K. 2014. Neoproterozoic mafic-ultramafic intrusions in the Fanjingshan region, South China: Implications for subduction related magmatism in the Jiangnan Fold Belt. Journal of Geology, 122, 455-473.

  4. Wang W and Zhou M-F. 2014. Provenance and tectonic setting of the Paleo- to Mesoproterozoic Dongchuan Group in the southwestern Yangtze Block, South China: implication for the breakup of supercontinent Columbia. Tectonophysics, v.610, p.110-127.

  5. Li, X.Y., Zheng, J.P., Sun, M., Pan, S.-K., Wang, W., Xia, Q.-k., 2014. The Cenozoic lithospheric mantle beneath the interior of South China Block: Constraints from mantle xenoliths in Guangxi Province. Lithos 210-211, 14-26.

  6. Zhou, M.-F., Zhao, X.-F., Chen, W.T., Li, X.-C., Wang, W., Yan, D.-P., Qiu, H.-N., 2014. Proterozoic Fe-Cu metallogeny and supercontinental cycles of the southwestern Yangtze Block, southern China and northern Vietnam. Earth-Science Reviews 1396, 59-82.

  7. Chen, W. T., Sun, W.-H., Wang, W., Zhao, J.-H., and Zhou, M.-F., 2014, “Grenvillian” intra-plate mafic magmatism in the southwestern Yangtze Block, SW China: Precambrian Research, v. 242, p. 138-153.

  8. Wang, W and Zhou, M.F., 2013. Petrological and geochemical constraints on provenance, paleoweathering and tectonic setting of the Neoproterozoic sedimentary basin in the eastern Jiangnan Orogen, South China. Journal of Sedimentary Research, v.83, p. 974-993

  9. Wang, W., Zhou, M.F., Yan, D.P., Li, L., Malpas, J., 2013. Detrital record of active-margin sedimentation and its implication in tectonic evolution: constraints from U-Pb dating and Hf isotope of detrital zircons from the Precambrian sedimentary sequences in the eastern Jiangnan Orogen, South China. Precambrian Research, 253.1-19.

  10. Wang, B.-Q., Wang, W., Chen, W.-T., Gao, J.-F., Zhao, X.-F., Yan, D.-P., Zhou, M.-F., 2013. Constraints of detrital zircon U-Pb ages and Hf isotopes on the provenance of the Triassic Yidun Group and tectonic evolution of the Yidun Terrane, Eastern Tibet. Sedimentary Geology, 289, 74-98

  11. Wang B-Q,Wang W,Zhou M-F,2013. Provenance and tectonic setting of the Triassic Yidun Group, the Yidun Terrane, Tibet,Geoscience Frontiers,v. 6, p.765~777

  12. Liu, B.X., Qi, Y., Wang, W., Siebel, W., Zhu, X.Y., Nie, H., He, J.F., Chen, F.K. 2013. Zircon U-Pb ages and O-Nd isotopic composition of basement rocks in the North Qinling Terrain, central China: evidence for provenance and evolution. International Journal of Earth Sciences, v.102, p.2153-2173

  13. Wang, W., Chen, F. K., Hu, R., Chu, Y., and Yang, Y. Z., 2012, Provenance and tectonic setting of Neoproterozoic sedimentary sequences in the South China Block: evidence from detrital zircon ages and Hf–Nd isotopes: International Journal of Earth Sciences, v.101, p. 1723-1744.

  14. Wang, W and Zhou, M.-F. 2012. Sedimentary records of the Yangtze Block (South China) for its correlation with adjacent continents in Neoproterozoic. Sedimentary Geology, v. 265-266, p. 126-142.

  15. Wang, W*., Zhou, M.-F., Yan, D.-P., and Li, J.-W., 2012, Depositional age, provenance, and tectonic setting of the Neoproterozoic Sibao Group, southeastern Yangtze Block, South China: Precambrian Research, v. 192-195, p. 107-124.

  16. Wang, W*., Wang, F., Chen, F., Zhu, X., Xiao, P., and Siebel, W., 2010, Detrital Zircon Ages and Hf‐Nd Isotopic Composition of Neoproterozoic Sedimentary Rocks in the Yangtze Block: Constraints on the Deposition Age and Provenance: The Journal of Geology, v. 118, p. 79-94.

  17. Wang, W., Chen, R. X., Chen, F., and Zheng, Y. F., 2010, Isotopic disequilibrium in ultrahigh-pressure and retrograde metamorphism of eclogite and gneiss from the Chinese Continental Scientific Drilling in the Sulu orogen, China: evidence from mineral Nd–Sr–O isotopic composition: International Journal of Earth Sciences, v. 99, p. 727-743.

  18. Chen, F.K., Zhu, X.Y., Wang, W., Wang, F., Hieu, P., and Siebel, W., 2009, Single-grain detrital muscovite Rb-Sr isotopic composition as an indicator of provenance for the Carboniferous sedimentary rocks in northern Dabie, China: Geochemical Journal, v. 43, p. 257-273.

  19. Zhou, M.F., Zhao, J.H., Jiang, C.Y., Gao, J.F., Wang, W., and Yang, S.H, 2009, OIB-like, heterogeneous mantle sources of Permian basaltic magmatism in the western Tarim Basin, NW China: Implications for a possible Permian large igneous province: Lithos, v. 113, p. 583-594.

  20. Trung Hieu Pham., Chen, F.K., Zhu, X.Y.,Wang W., Nguyen TBT., Bui, MT and Nguyen, Q.L.2009, Zircon U-Pb ages and Hf isotopic composition of the Posen granite in northwestern Vietnam. Acta Petrologica Sinica. v. 25, p.3141-3152. (in Chinese with English abstract)

  21. Zhu, X.Y., Chen, F.K., Yang, L., Wang, W., Trung Hieu Pham., Miao, L.C., Zhang, F.Q. 2009. Zircon Hf isotopic composition and source characteristics of the Wudang Group in the Qinling orogenic belt, western Henan Province. Acta Petrologica Sinica. v. 25, p.3017-3028. (in Chinese with English abstract)

  22. Chu, Z.Y., Wang W., Chen, F.K., Wang, X.L., Li, X.H and Ji, J.Q, 2009.Os-Nd-Pb-Sr isotopic compositions of the Santaishan ultramafic rock in western Yunnan and its geological significances. Acta Petrologica Sinica,v. 12, p. 3221-3228 (in Chinese with English abstract)

  23. 祝禧艳,陈福坤,王伟,PHAM Trung Hieu,王芳,张福勤, 2008.豫西地区秦岭造山带武当群火山岩和沉积岩锆石U-Pb年龄,地球学报.06:3017~3028

  24. 储著银,陈福坤,王伟,谢烈文,杨岳衡,2007.微量地质样品铼锇含量及其同位素组成的高精度测定方法,岩矿测试,06:431~435

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