Lu Wang
wanglu@cug.edu.cn, wangluouc@qq.com
Professor
State key laboratory of Geological Processes and Mineral Resources (GPMR),
China University of Geosciences, Wuhan
68 Jincheng Street, East Lake Hi-Tech Development Zone, 430078, Wuhan, China
https://www.scopus.com/authid/detail.uri?authorId=35575221300
https://orcid.org/0000-0002-4526-5366
Education & Employment
Oct. 2021-present: Party Secretary for State Key Lab of Geological Processes and Mineral Resources, China University of Geosciences, Wuhan
Jan. 2018-present: Full Professor at State Key Lab of Geological Processes and Mineral Resources, China University of Geosciences, Wuhan
2011-2017: Associate Professor (Ph.D. supervisor since 2015) at State Key Lab of Geological Processes and Mineral Resources, China University of Geosciences, Wuhan
2005 - 2011: Lecturer at Department of Marine Geology, Ocean University of China, Qingdao, China
2010-2011: Postdoctoral Researcher in the Solid Geophysics Department, China University of Geosciences, Wuhan
2008-2009: Visiting Scholar at Earth & Atmospheric Science Department, Center for Env. Science, Saint Louis University, Missouri, USA
1999-2005: Master-Ph.D in Structural Geology, at Department of Earth Sciences, China University of Geosciences, Wuhan, China (Ph.D. Thesis in microfabric and P-T-t-Deformation evolution of UHP metamorphic rocks from Dabie Mountain, China)
May-Oct., 2001 International Cooperative Research Education in Microfabrics, at Technique University of Munich, Germany, supported by DAAD
Feb. 1999: Minor B.S., Science and Technology English, at Foreign Language Department, Huazhong University of Science and Technology, China
1995-1999: B.S., in Geology, at Department of Earth Sciences, China University of Geosciences, Wuhan, China (Bachelor thesis in Sedimentary Geology in the Liaohe Oil Field, Northern China)
Research Fields
She engaged her Ph.D in the study of microstructure and P-T-t-D path of ultrahigh pressure eclogite and jadeite quartzite in the Dabie Mountain. Her expertise is integrating the structural analysis from the field to the microstructures in the lab, with petrology, geochemistry and geochronology to re-establish the physical and chemical evolution process, thus to understand the orogenesis and their geodynamics at Phanerozoic and Precambrian convergent plate boundaries. In the past decades, her research is mainly focused on the following two topics:
1) Deformation - metamorphism - melting fluid evolution history of ultrahigh pressure metamorphic rocks in Dabie-Sulu orogenic belt. Melt-fluid activity in the subduction zone plays an important role in the rapid exhumation of the deeply subducted crustal material, the magmatic activity and the growth of the continental crust. She reported the first case of large-scale partial melting of UHP eclogite, forming migmatized eclogite during its exhumation. After that, she leads her research group systematically studies its melting reactions and mechanisms, source of the melt, strain localization and microfabrics variation corresponding to melt-fluid events at different stages of exhumation. Her target is to establish the spatio-temporal evolution sequence of P-T-t-D-Melting along the strike of the orogenic belt and figure out the variation rules, as well as its influence on the deformation differentiation, rheological properties and rapid exhumation of subducted materials, so as to deeply understand the physical and chemical evolution process during the exhumation of the continental collision orogenic belt, and provide a basis for the crust-mantle reaction, the formation and evolution of the continental crust and the exhumation dynamics mechanism. The results were published in Nature Communications, EPSL, GSAB, JMG, Lithos and other top journals.
2) Index features for Archean plate tectonic initiation and style. When and how the modern plate tectonic style started is one of the hottest issues and frontier scientific problems in the early evolution of the earth. Focusing on the typical structural, petrology and UHP mineralogical evidences in the Phanerozoic modern plate tectonic style, the Archean tectonic melánge belt, which extends 1600 km from the south to the north of the central orogenic belt of the North China craton, is the natural laboratory, Identify and report the characteristics of modern plate tectonics such as large transverse plate tectonics (large thrust nappe structures), eclogite facies metamorphosed subduction oceanic crust and ultra-high pressure minerals in pod-shaped chromite, which have been formed 2.5 billion years ago. It provides a systematic sign and geological basis for the start of the Archean modern plate tectonics. The results were published in Nature Communications, PNAS, Earth Science Review, EPSL, Geology, GSA Bulletin, Precambrian Geology and other top journals.
Taking the Archean tectonic melánge belt, that extending 1600km from the north to the south, from the Central Orogenic Belt of the North China craton as a natural laboratory, searching for the typical structural, petrology and UHP mineralogical evidence that is representative under the Phanerozoic modern plate tectonic regime. Our research team has identified and reported the oldest structure derived from large-scale subhorizontal plate movement (huge thrust nappe structure), Eclogite-facies metamorphosed subducted oceanic crust and UHP minerals in podiform chromite formed >2.5 billion years ago, provide systematic evidences and geological basis for the initiation of modern plate tectonics in Archean.
In the future, we will continue to work on the mechanism, time limit and melt composition of crust melting under compression-extension conditions (accretion-collision orogenic belt, subduction zone) and different tectonic settings through time (Archean to Phanerozoic) in the world and their contribution to the new grown crust.
More than 70 articles have been published. For published articles please visit https://www.scopus.com/authid/detail.uri?authorId=35575221300
Present Research Interests
l Fluid-melt activities of UHP-HP metamorphic rocks and their geodynamic significance from convergent plate boundaries
l Structural-metamorphic evolution, petro-geochronology of high-grade metamorphic rocks and their correlations with melt-fluid activities, arc magmatism, slab failure in collisional mountain belts
l Petrofabrics and rheology on UHP rocks influenced by partial melting and fluid activities
l Archean tectonics, structural-metamorphic evolution process of ophiolitic mélange, OPS
l UHP inclusions and mineral chemistry of podiform chromitites, especially in Precambrian podiform chromitites, and their implications for plate tectonics initiation in the Archean and deep element cycling
Editorial and Administrative Skills
l Scientific committee member, 14th Eclogite Conference, Lyon, France
l Editorial Board Member, Lithos, July, 2022-present
l (Scientific) Associate Editor, GSA Bulletin (GeoScienceWorld), 2020-present
l (Scientific) Associate Editor, Journal of Earth Science (Springer), 2010-present
l Associate Editor, Results in Geochemistry, (Elsevier Open Access), 2020-present
l Associate Editor, Geodinamica Acta, 2018-2021
l (Scientific) Associate Editor, Earth Science-Journal of China University of Geoscience, EI
l Co-section editor for Encyclopedia of Geology, Elsevier, structural geology and tectonics chapters
l Reviewer of submitted papers from journals e.g. Nature Communications, Geology, GSA Bulletin, Lithos; Reviewers of Master-Ph.D theses major in Geology from different universities of China; Proposal Reviewer from National Science Foundation of China;
l Executive Director of Center for Global Tectonics, China University of Geosciences, Wuhan. Tasks: proposal writing and defense, international conference organizer, lab-construction and organization of international collaboration between university professors within China and Outside China.
Awards
l Youth Geological Science and Technology Award, Geological Society of China, 2015
l First award of Excellent Academic Paper, Hubei Province, 2014
l Natural Science Award of Hubei Province, 2019
l Excellent Undergraduate Thesis Supervisor, Hubei Province, 2017
l Excellent Ph.D. Thesis Supervisor, CUG Wuhan, 2017
l Excellent postdoc supervisor, CUG Wuhan, 2021
l Excellent undergraduate tutor, CUG Wuhan, 2022
l Hundred excellent academic paper publication award, Compilation of scientific research achievements on 70th anniversary, CUG Wuhan, 2022 70周年校庆系列科研成果汇编:百篇优秀学术成果集(2012-2021)
Research Grants
1. P.I., GPMR MOST Special Fund, Record of geological process at the rigid plate boundaries of early earth: implications to ore-deposit resources and habitable earth, 2022.1-2024.12, MSFGPMR2022-7
2. P.I., National Natural Science Foundation of China, Partial melting of meta-basic rocks in the northern Sulu orogen: correlations among structural geology, P-T-t path and melt-fluid evolution, 2021.1-2024.12, Grant No.: 40272228
3. Co. P.I., National Science Foundation of China, China-Mongolia Science and Technology Collaboration Fund, Accretionary tectonics in the SE Mongolia: implications for correlation with the Chinese segment of CAOB, 2020.1-2022.12, Grant No.: 41961144020
4. Co. P.I., National Science Foundation of China, Key Project from the Key Research Program “Geodynamic Systems of the Tethys”, Lateral escape and the Formation of New Plate Boundaries During Continental Collision. 2018.1-2021.12, Grant No.: 91755213.
5. P.I., National Natural Science Foundation of China, P-T-t-Deformation-Melting evolution process of UHP eclogite and its rheological significance, 2016.1-2019.12, Grant No.: 41572182,
6. P.I., the Fundamental Research Funds for the Central Universities, "Tengfei Program", G1323511572, Partial melting of HP-UHP metamorphic rocks within subduction zone, 2015.1-2017.12
7. P.I., the Fundamental Research Funds for the Central Universities, 2012219279-CUG120818, Preservation of intergranular coesite and deformation mechanism within UHP eclogite from Yangkou Bay, Sulu orogen. 2013.1-2014.12
8. P.I., National Natural Science Foundation of China, Partial melting of deep subducted eclogite and its rheological significance to the continental collision, 2013.1-2016.12, Grant No.: 41272225
9. P.I., National Natural Science Foundation of China, High precision structural analysis and rheology study on multistage overprinted folding events in UHP-HP metamorphic terrain, Yangkou. 2009.1-2011.12,Grant No:40802045
10. P.I., Natural Science Foundation of Shandong Province. Structural Evolution and High precision structural analysis of multistage overprinted folding events in UHP-HP metamorphic terrain, Yangkou. 2009.1-2011.12,Grant No:Q2008E03.
11. P.I., China Postdoctoral Science Foundation, Microstructures characters and tectonic significances of Miaowan ophiolite rocks in Southwestern Huangling anticline. 2010.7-2011.12; Grant No.: 20100471203
12. P.I., Special Fund for Outstanding Postdoctoral Research, Geometry and geneisis of In-situ partial melting of UHP eclogite in Sulu belt, China; 2011.1-2012.12; Grant No.: 201104495
13. P.I., Opening fund from Three Gorges Geohazards Research Center, Ministry of Education, China University of Geosciences, Wuhan, China. Microstructures characters and tectonic significances of ultramafic rocks (Miaowan Ophiolite rocks) in Southwestern Huangling anticline, Three Gorges reservoir area. 2010. 1-2011.12. Grant No.: TGRC201024
14. Co. P.I., National Science Foundation of China, Key Project from the Key Research Program, Global comparison between North China craton and world classical craton: Implications to the decratonization and continental growth. 2011.1-2014.12, P.I. Prof. Timothy Kusky, Grant No.: 91014002.
15. Co. P.I., Robert Bosch Fund from Germany(Science Bridge: Asia Grant Request for Support for an Initiation Project), Grant No.:32.5.8003.0105.0, P.I., Prof. Joern Kruhl, Technique University of Munich, Germany, 2011.9-2012.4
Teaching Activities
2005-2007 Tectonics and Regional Geology of China, undergraduate course, Ocean University of China
2006-2008 Marine Geology-Plate tectonics, undergraduate course, Ocean University of China
2006-2007 Field digital mapping course in Chaohu, Anhui Province, China, Marine Geology major undergraduate students, Ocean University of China
2005-2008 Class tutor in Marine Geology for undergraduate student, Ocean University of China
2008-2009 Supervise SRTP (student research training program) project for undergraduate students in Ocean University of China
2015-present Global Tectonics, Master-Ph.D. student, University of China Academy of Sciences, co-teaching with Prof. Tim Kusky, bilingual teaching
2016-present Global Tectonics, undergraduate students, China University of Geosciences, Wuhan, co-teaching with Prof. Tim Kusky, bilingual teaching
2019 Physical Geology (Metamorphic Geology Chapter), international elite class for undergraduate students, China University of Geosciences, Wuhan, English teaching
2016-present Senior Analytical Structural Geology, Master-Ph.D. students, China University of Geosciences, Wuhan
2016-present Large Equipment Theory and Application, SEM, Master students, China University of Geosciences, Wuhan
2018-2022 Class tutor (Academic supervisor) for undergraduate students, International geology elite class, Grade 2018, school of earth sciences, China University of Geosciences, Wuhan (invited)
2022-present Class tutor (Academic supervisor) for undergraduate students, National Everest geology class, Grade 2022, School of Earth Sciences, China University of Geosciences, Wuhan (invited)
2023 Integrated Structural Geology, National Everest geology class, Grade 2021, school of earth sciences, China University of Geosciences, Wuhan (invited)
Publications
1. Peng Feng, Lu Wang*, Xiawen Li, Wenjie Ding, Zhe Chen, 2023, SS-LASS Zircon Dating Deciphering Multiple Episodes of Anatexis in A Deeply-subducted Continental Crust: An Example from Sulu Orogen, China, Journal of Earth Science, https://doi.org/10.1007/s12583-022-1797-8, in press.
2. Peng, Y., Kusky, T.*, Wang, L.*, Luan, Z., Wang, C., Liu, X., Zhong, Y., Noreen J.E., 2022, Passive margins in accreting Archaean archipelagos signal continental stability promoting early atmospheric oxygen rise. Nature Communications 13, 7821. doi.org/10.1038/s41467-022-35559-w
3. Ning, W.B., Kusky, T.M.*, Wang, L.*, Huang, B. Archean eclogite-facies oceanic crust indicates modern-style plate tectonics, PNAS, 2022, DOI: 10.1073/pnas.2117529119
4. Kusky, T.*, Huang, Y., Wang, L.*, Robinson, P., Wirth, R., Polat, A., Hu, Wei, 2022, Vestiges of early Earth’s deep subduction and CHONSP cycle recorded in Archean ophiolitic podiform chromitites, Earth Science Reviews, doi.org/10.1016/j.earscirev.2022.103968,
5. Kusky, T. and Wang, L., 2022. Growth of continental crust in intra-oceanic and continental margin arc systems: analogs for Archean systems. Science China Earth Sciences (1674-7313).
6. Wang, Z., Kusky, T. and Wang, L., 2022. Long-lasting viscous drainage of eclogites from the cratonic lithospheric mantle after Archean subduction stacking. Geology, 50(5): 583-587.
7. Zhong, Y., Kusky, T.M.* and Wang, L.*, 2022. Giant sheath-folded nappe stack demonstrates extreme subhorizontal shear strain in an Archean orogen. Geology, 50(5): 577-582.
8. Wang, S.J., Brown, M., Wang, L., Johnson, T., Olierook, H.K.H., Kirkland, C. L., Clark, A. K., Evans, N.J., and McDonald B.J., Two-stage exhumation of deeply subducted continental crust: Insight from zircon, titanite, and apatite petrochronology, Sulu belt of eastern China. GSA Bulletin, 2022, https://doi.org/10.1130/B36309.1
9. Zhong, Y.T., Kusky, T.M*., Wang, L*., Polat, A., Peng, Y.Y., Luan, Z.K., Liu, X.Y., and Wang, C.H., Wang, J.P., 2021, Alpine-style nappes thrust over ancient North China continental margin demonstrate large Archean horizontal plate motions: Nature Communications, 12, 6172. https://doi.org/10.1038/s41467-021-26474-7.
10. Wang L., Wang S.J., Feng P., Wang Z.C., Brown M., Johnson M., 2021. Multiple Genesis of Fluid and Melt during Exhumation of Deeply-subducted UHP Eclogite. Acta Geologica Sinica (English Edition), 95(supp. 1): 65–67.
11. Deng, H., Jia, N., Kusky, T., Polat, A., Peng, G., Huang, B., Wang, L., Wang, JP., 2021. From subduction initiation to hot subduction: Life of a Neoarchean subduction zone from the Dengfeng Greenstone Belt, North China Craton. GSA Bulletin, 134(5-6): 1277-1300.
12. Wang, L., Kusky, T.M.*, Zhang, Y.J., Lentz, D., Zhong, Y.T., Ding, W.J., Deng, H., Giddens, R., Peng, S.B. Extreme Sulfur Isotope Fractionation of Hydrothermal Auriferous Pyrites from the SW Fringe of the Taupo Volcanic Zone, New Zealand: Implications for Epithermal Gold Exploration, Results in Geochemistry, 2021
13. Huang, Yang, Wang, Lu*, Robinson, P.T., Ning, W.B., Zhong, Y.T., Wang, J.P., Hu, W., Polat, A., Kusky, T.M*. Podiform chromitite genesis in an Archean juvenile forearc setting: The 2.55 Ga Zunhua chromitites, North China Craton, Lithos, 2021, 394-395, 106194.
14. Feng, Peng, Wang, Lu*, Brown M., Johnson, Tim E, Kylander-Clark, Andrew, Piccoli, Philip M. Partial melting of ultrahigh-pressure eclogite by omphacite-breakdown facilitate drive exhumation of deeply-subducted crust. Earth and Planetary Science Letters, 2021,554, 116664.
15. Wang, S. J., Wang, L*., Ding, Y., Wang, Z.C., 2020. Origin and Tectonic Implications of Post-Orogenic Lamprophyres in the Sulu Belt of China. Journal of Earth Science, 31(6): 1200–1215. https://doi.org/10.1007/s12583-020-1070-y. http://en.earth-science.net
16. Feng, P., Wang, L.*, Brown, M., Wang, S.J., and Li, X.W., 2019, Separating multiple episodes of partial melting in polyorogenic crust: An example from the Haiyangsuo complex, northern Sulu belt, eastern China: Geological Society of America Bulletin, https:// doi.org/10.1130/B35210.1, Oct. 2019; v. 132(5-6):1235–1256
17. Wang, S.J., Wang, L. *, Brown, M. *, Johnson, T..E., Piccoli, P.M., Feng, P., Wang, Z.L., Petrogenesis of leucosome sheets inmigmatitic UHP eclogites—Evolutionfrom silicate-rich supercritical fluid to hydrous melt, 2020, Lithos, 360-361, https://doi.org/10.1016/j.Lithos.2020.105442
18. Kusky, T.M., Wang, J.P., Wang, L., Huang, B., Ning, W.B., Fu, D., Peng, H.T., Deng, H., Polat, A., Zhong, Y.T., and Shi, G.Z., 2020, Melanges through time: Life Cycle of the world’s largest Archean mélange compared with Mesozoic and Paleozoic subduction-accretion-collision mélanges, Earth Science Reviews 209, 103303. https://doi.org/10.1016/j.earscirev.2020.103303
19. Ning, W.B., Kusky, T.*, Wang, J.P., Wang, L., Deng, H., Polat, A., Huang, B., Peng, H.T., and Feng, P., 2020, From subduction initiation to arc-polarity reversal: Life cycle of an Archean subduction zone from the Zunhua ophiolitic mélange, North China Craton, Precambrian Research 350, 105868. https://doi.org/10.1016/j.precamres.2020.105868
20. Huang, B., Kusky, T.*, Johnson, T., Wilde, S., Wang, L., Polat, A., and Fu, D., 2020, Paired metamorphism in the Neoarchean: a record of accretionary-to-collisional orogenesis in the North China Craton, Earth and Planetary Science Letters, v. 543, 116355, https://doi.org/10.1016/j.epsl.2020.116355
21. Wang* L, Wang S., Brown M., Xia B., Kusky T., Polat A., Piccoli P., Johnson T. Ten years of research progress on the structure, P–T path and Fluid–Melt evolution of the deeply‐subducted UHP continental crust in the Sulu belt. Acta Geologica Sinica‐English Edition 93, 122-123,2019
22. Deng, H., Kusky, T.M., Polat, A., Fu, H.Q., Wang, L., Wang, J.P., Wang, S.J., Zhai, W.J., 2020. A Neoarchean Arc-Backarc Pair in the Linshan Massif, Southern, North China Craton. Precambrian Research, 341: 105649.
23. Parlak, O., Dunkl, I., Karaoğlan, F., Kusky, T.M., Zhang, C., Wang, L., Köpke, J., Billor, Z., Hames, W.E., Şimşek, E., Şimşek, G., Şimşek, T., and Öztürk, S.E., 2019, Rapid cooling history of a Neotethyan ophiolites: Evidence for contemporaneous subduction and metamorphic sole formation: Accepted by Geological Society of America Bulletin. https://doi.org/10.1130/B35040.1, 2019.
24. Huang, B., Kusky, T.M.*, Wang, L., Polat, A., Fu, D., Windley, B.F., Deng, H., and Wang, J.P., 2018, Structural relationships and kinematics of the Neoarchean Dengfeng forearc and accretionary complexes, southern North China craton: Geological Society of America Bulletin, v. 131, p. 966-996, https://doi.org/10.1130/B31938.1.
25. Huang, B., Kusky, T.M., Wang, L., Deng, H., Wang, J., Fu, D., Peng, H., Ning, W., 2019. Age and genesis of the Neoarchean Algoma-type banded iron formations from the Dengfeng greenstone belt, southern North China Craton: Geochronological, geochemical and Sm–Nd isotopic constraints. Precambrian Research 333, 105437.
26. Wang, J.P., Li, X.W., Kusky, T.M.*, Ning, W.B., Wang, L., Polat, A., and Deng, H., 2019, Geology of a Neoarchean suture: Evidence from the Zunhua ophiolitic melange of the Eastern Hebei Province, North China Craton: Accepted by Geological Society of America Bulletin, https://doi.org/10.1130/B35138.1.
27. Xia, B., Brown, M., Wang, L., Wang, S.J., and Piccoli, P., 2018, Phase equilibrium modeling of MT–UHP eclogite: a case study of coesite eclogite at Yangkou Bay, Sulu Belt, Eastern China: Journal of Petrology, v.59(7), p.1253-1280, https://doi.org/ 10.1093/petrology/egy060.
28. Wang, L., Wang, S.J., Brown, M., Zhang, J.F., Feng, P. and Jin, Z. M., 2018, On the survival of intergranular coesite in UHP eclogite: Journal of Metamorphic Geology, v. 36, p. 173-194, https://doi.org/10.1111/jmg.12288.
29. Wang L., Kusky T.M., Polat A., Wang S.J., Jiang X.F., Zong K.Q., Wang J.P., Deng H., Fu J.M, 2014, Partial melting of deeply subducted eclogite from the Sulu Orogen in China: Nature Communications v. 5, p. 5604, https://doi.org/ 10.1038/ncomms6604 (2014).
30. Wang, S.J., Wang, L., Brown, M., Piccoli, P.M., Johnson, T.E., Feng, P., Deng, H., Kitajima, K., and Huang, Y., 2017, Fluid generation and evolution during exhumation of deeply subducted UHP continental crust: Petrogenesis of composite granite-quartz veins in the Sulu belt, China: Journal of Metamorphic Geology, v. 35, p. 601–629, https://doi.org/10.1111/jmg.12248.
31. Wang, S.J., Wang, L., Brown, M., and Feng, P., 2016, Multi-stage barite crystallization in partially melted UHP eclogite from the Sulu belt, China: American Mineralogist, v. 101, p. 564–579, https://doi.org/10.2138/am-2016-5384.
32. Jiang, X.F., Peng, S.B., Kusky, T.M., Wang, L., and Deng, H., 2018, Petrogenesis and geotectonic significance of Early-Neoproterzoic olivine-gabbro within the Yangtze Craton: constrains from the mineral composition, U-Pb age and Hf isotopes of zircons: Journal of Earth Science, v. 29(1), p. 93-102, https://doi.org/10.1007/s12583-018-0885-2.
33. Huang, Y., Wang, L. *, Kusky, T., Robinson, P.T., Peng, S. B, Polat, A. and Deng, H., 2017, High-Cr chromites from the Late Proterozoic Miaowan Ophiolite Complex, South China: Implications for its tectonic environment of formation: Lithos, v. 288, p. 35-54, https://doi.org/10.1016/j.lithos.2017.07.014.
34. Wang J.P., Kusky T.M.*, Wang L., Polat A., Deng, H., Wang, C., and Wang, S.J., 2017, Structural relationships along a Neoarchean arc-continent collision zone, North China Craton: Geological Society of America Bulletin, v. 129 (1-2), p. 59-75, https://doi.org/10.1130/B31479.1.
35. Wang J.P., Kusky T.M. *, Wang L., Polat A., Wang, S.J., Deng, H., Fu, J.M., and Fu, Dong, 2017, Petrogenesis and geochemistry of circa 2.5 Ga granitoids in the Zanhuang Massif: Implications for magmatic source and Neoarchean metamorphism of the North China Craton: Lithos, v. 268, p. 149-162, https://doi.org/10.1016/j.lithos.2016.10.028.
36. Jiang, X.F., Peng, S.B. *, Kusky, T., Wang, L., Deng, H., and Wang, J.P., 2017, Formation time of the Northeastern Jiangxi ophiolite in the Eastern Jiangnan Orogenic Belt: evidence from LA-ICP-MS Zircon U-Pb Dating of the Gabbro: Geoscience, v. 31(4), p. 1-9. (in Chinese)
37. Deng, H., Peng, S. B.*, Polat, A., Kusky, T., Jiang, X.F., Han, Q.S., Wang,L., Huang, Y., Wang, J.P., Zeng, W., and Hu, Z.X., 2017, Neoproterozoic IAT intrusion into Mesoproterozoic MOR Miaowan ophiolite, Yangtze Craton: evidence for evolving tectonic settings: Precambrian Research, v. 289, p.75-94, https://doi.org/10.1016/j.precamres.2016.12.003.
38. Liu, X.W., Xie, Z.J., Wang,L., Xu, W., and Jin, Z.M., 2016, Water incorporation in garnets from ultrahigh pressure eclogites at Shuanghe, Dabieshan: Mineralogical Magazine, v. 80(6), p. 959-975, https://doi.org/10.1180/minmag.2016.080.034.
39. Polat, A., Wang, L., and Appel, P.W, 2015, A review of structural patterns and melting processes in the Archean craton of West Greenland: Evidence for crustal growth at convergent plate margins as opposed to non-uniformitarian model: Tectonophysics, v. 662, p. 67-94, https://doi.org/10.1016/j.tecto.2015.04.006.
40. Deng H., Kusky, T.M.*, Polat, A., Wang, C., Wang, L., Li, Y.X., and Wang, J.P., 2016, A 2.5 Ga fore-arc subduction-accretion complex in the Dengfeng Granite-Greenstone Belt, Southern North China Craton: Precambrian Research, v. 275, p. 241-264, https://doi.org/10.1016/j.precamres.2016.01.024.
41. Jiang, X.F., Peng, S.B.*, Polat, A., Kusky, T., Wang, L., Wu, T.Y., Lin, M.S., Han, Q.S., 2016, Geochemistry and geochronology of mylonitic metasedimentary rocks associated with the Proterozoic Miaowan Ophiolite Complex, Yangtze craton, China: Implications for geodynamic events: Precambrian Research, v. 279, p. 37-56, https://doi.org/10.1016/j.precamres.2016.04.004.
42. Wang, J.P., Kusky, T.M.*, Wang, L., Polat, A., and Deng, H., 2015, A Neoarchean subduction polarity reversal event in the North China Craton: Lithos, v. 220-223, p. 133-146, https://doi.org/10.1016/j.lithos.2015.01.029.
43. Kusky, T.M., Windley, B.F., Wang, Lu, Wang, Z.S., Li, X.Y., Zhu, P.M., 2014, Flat slab subduction, trench suction, and craton destruction: Comparison of the North China, Wyoming, and Brazilian craton: Tectonophysics, v. 630, p. 208-221, https://doi.org/10.1016/j.tecto.2014.05.028.
44. Wang, S.J., Wang, L.*, Fu, J.M., and Ding, Y., 2014, A new perspective for research of Dabie-Sulu Ultrahigh-Pressure Metamorphic Rocks: Application of Optical Microscope-Based Cathodoluminescence: Earth Science, v. 39(3), p. 357-367 (in Chinese).
45. Zhang, L.*, Wang L., Yin, K.D.*, Lü, Y., Zhang, D.R., Yang, Y.Q., Huang, X.P., 2013, Pore water nutrient characteristics and the fluxes across the sediment in the Pearl River estuary and adjacent waters, China: Estuarine, Coastal and Shelf Science, v. 133, p.182-192, https://doi.org/10.1016/j.ecss.2013.08.028.
46. Wang, L., Kusky, T., and Santosh, M., 2012, On the role of dual active margin collision for exhuming the world’s largest ultrahigh pressure metamorphic belt: Journal of Earth Science, v. 23, p. 802-812, https://doi.org/10.1007/s12583-012-0292-z.
47. Kusky, T.M., Wang, L., Dilek, Y., Robinson, P., Peng, S.B. and Huang X.Y., 2011, Application of the modern ophiolite concept with special reference to Precambrian ophiolites: Science China, v. 54(3), p. 315-341, https://doi.org/10.1007/s11430-011-4175-4.
48. Wang, L., Jin, Z.M., Kusky, T.M., Liu, X.W., and Xu, H.J., 2010, Microfabric characteristics and rheological significance of jadeite-quartzite from Shuanghe, Dabie Mountains: Journal of Metamorphic Geology, v. 28, p. 163-182, https://doi.org/10.1111/j.1525-1314.2009.00859.x.
49. Wang, L., Kusky, T., and Li, S.Z.,2010, Structural Geometry and Evolution of an Exhumed Ultra-High Pressure Eclogite Massif, Yangkou Bay, Sulu Belt, China: Journal of Structural Geology, v. 32, p. 423-444, https://doi.org/10.1016/j.jsg. 2010.01.012.
50. Wang, L., Jin, Z.M. and He, M.C., 2003, Raman spectrum study on quartz exsolution in omphacite of eclogite and its tectonic significances: Earth Science-Journal of China University of Geosciences, v. 14(2), p. 119-126.
51. Deng, H., Kusky, T., Polat, A., Wang, J.P., Wang, L., Fu, J.M., Wang, Z.S., and Yuan, Y., 2014, Geochronology, mantle source composition and geodynamic constraints on the origin of Neoarchean mafic dikes in the Zanhuang Complex, Central Orogenic Belt, North China Craton: Lithos, v. 205, p. 359-378, https://doi.org/10.1016/j.lithos.2014.07.011.
52. Wang, J.P., Kusky, T.M., Polat, A., Wang, L., Deng, H., and Wang, S.J., 2013, A late Archean tectonic mélange in the Central Orogenic Belt, North China Craton: Tectonophysics., v. 608, p. 929-946, https://doi.org/10.1016/j.tecto.2013.07.025.
53. Deng, H., Kusky, T.M., Polat, A., Wang, L., Wang, J.P., and Wang, S.J., 2013, Geochemistry of Neoarchean mafic volcanic rocks and late mafic dikes and sills in the Zanhuang Complex, Central Orogenic Belt, North China Craton: Implications for geodynamic setting: Lithos, v. 175-176, p. 193-212, https://doi.org/10.1016/j.lithos.2013.05.007.
54. Zhang, J.F., Shi F., Xu, H.J., Wang, L., Feng, S.Y., Liu, W.L., Yang, Y.F., Green II, H.W., 2012, Petrofabric and strength of SiO2 near the quartz-coesite phase boundary: Journal of Metamorphic Geology, v. 31, p. 83-92, https://doi.org/10.1111/jmg.12006.
55. Wang, J.P., Kusky, T.M.*, Polat, A., Wang, L., Peng, S.B., Jiang, X.F., Deng, H., Wang, S.J., 2012, Sea-floor metamorphism recorded in epidosites from the ca.1.0 Ga Miaowan Ophiolite, Huangling Anticline: China. Journal of Earth Science, v. 23(5), p. 696-704, https://doi.org/10.1007/s12583-012-0288-8.
56. Deng, H., Kusky, T.M., Wang, L., Peng, S.B., Jiang, X.F., Wang, J.P., Wang, S.J., 2012, Discovery of a sheeted dike complex in the Northern Yangtze Craton and its Implications for Craton evolution: Journal of Earth Science, v. 23, p. 676-695, https://doi.org/10.1007/s12583-012-0287-9.
57. Peng, S.B., Kusky, T.M., Jiang, X.F., Wang, L., Wang, J.P., and Deng, H, 2011, Geology, geochemistry, and geochronology of the Miaowan ophiolite, Yangtze craton: Implications for South China’s amalgamation history with the Rodinian supercontinent: Gondwana Research, v. 21, p. 577-594, https://doi.org/10.1016/j.gr.2011.07.010.
58. Santosh, M., Kusky, T., and Wang, L., 2011, Supercontinent cycles, extreme metamorphic processes and changing fluid regimes: International Geology Review, v. 53, p. 1403-1423, ` https://doi.org/10.1080/00206814.2010.527682.
59. 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, v. 504, p. 25-42, https://doi.org/10.1016/j.tecto.2011.01.017.
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 Dabie orogen of China: constraints from structural geology: Tectonophysics, v. 490, p. 267-293, https://doi.org/10.1016/j.tecto.2010.05.010
61. Zhang, L., Wang, L., Yang, Y.Q., Zhang, D.R, 2009, Cu Environmental Geochemical Characteristics in the Soil and Water in in copper-rich deposits of Southeastern Hubei Province, along the Middle Yangtze River, Central China: Environmental Pollution, v. 157, p. 2957–2963, https://doi.org/10.1016/j.envpol.2009.06.008.
62. 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 Research, v. 12, p.121-143, https://doi.org/10.1016/j.gr.2006.11.011Get rights and content.
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64. Wang, L., Jin, Z.M., and Zhang, J.F., 2005, Proceeding of Research on Fabric and Deformation Mechanisms of Omphacite in Ultra-high Pressure Metamorphic Eclogite: Geological Science and Technology Information, v. 24(1), p. 19-24. (in Chinese)
65. Jin, Z.M., Zhang, J.F., Liu, X.W., and Wang, L, 2007, Study on Rheology of Ultra-High Pressure Eclogite: Geoscience, v. 21, p. 183-194. (in Chinese).
66. Peng, S.B., Li, C.N., Kusky, T.M., Wang, L., Zhang, X.J., Jiang. X.F., and Xiong, C.R., 2010, Discovery and its tectonic significance of the Proterozoic Miaowan ophiolites in the southern Huangling anticline,western Hubei, China: Geological Bulletin of China, v. 29(1), p. 8-20. (in Chinese).
67. Wu, Y., Jin, Z.M., Ou, X.G., Xu, H.J., and Wang, L., 2005, Lithospheric thermal structure beneath the area of the Chinese Continental Scientific Drilling Site (CCSD): Acta Petrologica Sinica, v. 21, p. 439-450. (in Chinese).
68. Ou X.G., Jin Z.M., and Wang L., 2004, Thermal conductivity and its anisotropy of rocks from the depth of 100-2000m mainhole of Chinese Continental Scientific Drilling: revelations to the study on thermal structure of subduction zone: Acta Petrologica Sinica, v. 20(1), p. 109-118. (in Chinese).
69. Xu, S.M., Li, S.Z., Wang, L., and Zhou, L.H., 2008, Distribution and sedimentary facies of mesozoic main target strata in south tidal land of huanghua depression: Marine geology & Quaternary Geology, v. 28(1), p. 61-68. (in Chinese).
70. Li SZ, Kusky TM, Zhao GC, Sun M, …Wang L. Mesozoic tectonics in the Eastern Block of the North China Craton: implications for subduction of the Pacific plate beneath the Eurasian plate. Geological Society Special Publication, 280, 171-188, 2007
71. 王淞杰,王璐等,大别-苏鲁超高压变质岩研究新思路: 偏光显微镜阴极发光技术的应用,地球科学,2014
Supervised Students
Current
l Ph.D students: Wang Zhuocheng, Hu Wei, Peng Yaying,
l Co supervised Ph.D students: Zhong Yating, Ning Wenbin
l Master students: Yang Xiandeng, Hu Die, Zhao Jiayin, Zhang Mengwei, Yan Chao
l Co supervised Master students: Wang Ruizhi, Lin Jingsong
Graduated
l Postdoc finished: Feng Peng, Huang Yang
l Graduated Ph.D students: Wang Songjie, Feng Peng, Huang Yang
l Graduated Master students: Ding Yue, Wang Songjie, Wang Zhenlong, Fu Huaqiang, Li Li, Chen Zhe
l Graduated undergraduated students: Huwei, Wang Zhuocheng, Jiang Changhong, Hu Die, Li Cao An La, Peng Yaying, Luan Zhikang, Liu Xuanyu
Conference Presentation and Talks
Invited talks and post-conference field guider
1. Wang Lu. Partial melting of UHP eclogites, Sulu belt, China—P–T conditions, fluid-melt evolution, deformation and implications for exhumation dynamics,International Eclogite Conference (IEC) 14th,2022-07-11,July 10-13, 2022, Lyon-France
2. Wang Lu. Discovery of Archean Eclogite Facies Subducted Oceanic Crust. Major NNSFC Project Annual Conference, “Continental crust evolution and early plate tectonics”, 2022-04-16, Xi’an. 太古宙榴辉岩相俯冲洋壳的发现,重大项目“大陆地壳演化与早期板块构造”2022年春季年会
3. Wang Lu. Keynote Talk. 73rd Turkey Geological Congress, Ankara, Turkey, May 24-28th, 2021. Adding time to the P-T history of deeply subducted intergranular coesite-bearing eclogite at Yangkou Bay, central Sulu belt, China.
4. Wang Lu. Invited Talk, 72nd Turkey Geological Congress, Ankara, Turkey, April, 20-29, 2018. Partial Melting of the Ultrahigh Pressure Eclogite in the Sulu Orogen, China: Melt Generation and Migrigation during Exhumation Process。
5. Wang Lu. Ten years research progress on the deeply subducted continental crust in the Sulu Orogen: structural, P-T-t path and melt-fluid evolution, Six symposium of Continental Geodynamics, Qingdao, Shandong Province. Invited talk and Post-meeting field guide to the migmatized eclogite location, General’s Hill, Qingdao. 苏鲁造山带深俯冲陆壳十年研究进展:构造,P–T–t 轨迹及熔流体演化,“大陆动力学第六次研讨会”-“多圈层相互作用与宜居星球”青岛会议, 青岛, 2018-10-9至2018-10-9.
6. Wang Lu. Constraints of new zircon chronology techniques (SS-LASS ICP-MS) on the metamorphic age of deeply subducted eclogites under limited fluid conditions. Beijing, China Geophysical Union Annual Meeting., 2018. SS-LASS ICP-MS锆石年代学新技术对有限流体条件下深俯冲榴辉岩变质年龄的制约, 2018年第五届CGU地球科学联合学术年会, 北京, 2018-10-22至2018-10-24..
7. Wang Lu. On the preservation of the intergranular coesite within the UHP eclogite, Sulu belt. The 4th Annual Meeting of China Geophysical Association, Oct., 2016, Beijing. 苏鲁造山带超高压榴辉岩中粒间柯石英的保留,2016年10月,北京,中国地球物理协会第4届年会。
8. Wang Lu. Partial melting of deeply subducted eclogite of Sulu belt. The 15th Annual Academic Conference of the Chinese Society of Mineral and Petro-geochemistry, Changchun, Jilin Province, Jun., 2015. 苏鲁深俯冲榴辉岩的部分熔融,2015年6月,吉林长春——中国矿物岩石地球化学学会第15届学术年会。
9. Wang Lu. Partial melting of deeply subducted eclogite in the Sulu orogen. Meeting of the Joint Academic Committee of the National Key Laboratory Alliance of Solid Earth Sciences, 2014. 固体地球科学重点实验室联盟联合学术委员会会议
10. Wang Lu. Partial Melting of Deeply Subducted Eclogite Implications for Melt Transport, Rheology and Decratonization. Eos Trans. AGU, 2010 Fall Meet. Suppl., V24B-07
Talks and Posters
1) Wang Lu. 2022.10.10. New age constraints on the P-T history of deeply subducted coesite-bearing eclogite at Yangkou bay, central Sulu betl, China. GSA2022, October 9-12, Denver, Colorado, USA. Oral presentation (online). DOI:10.1130/abs/2022AM-381617.
2) Wang Lu. 2022.10.11. Partial Melting of UHP eclogite during exhuamtion, sulu belt, China-Fluid-Melt evolution, deformation and implication for exhumation dynamics. GSA2022, October 9-12, Denver, Colorado, USA. Oral presentation (online). DOI:10.1130/abs/2022AM-381676
3) Wang, L., and T.M. Kusky, 2010, Structural geometry of an exhumed UHP terrane in Yangkou Bay, the eastern Sulu orogen, China: Implications for continental collision processes Tectonic Crossroads: Evolving Orogens of Eurasia-Africa-Arabia Conference, GSA, Ankara, Turkey, on 4-8 October. Oral presentation.
4) Wang Lu and T.M. Kusky. Structural Geometry of an Ehumed UHP terrain in the eastern Sulu Orogen, China: Implications for Continental Collisioinal Processes. The 3rd IAGR (International Association of Gondwana Research, Gondwana to Asia Symposium) International Conference, Oral Talk
5) Wang Lu. 2018. Partial Melting of the Ultrahigh Pressure Eclogite in the Sulu Orogen, China: Melt Generationand Migration during Exhumation Process, 71rd Turkey Geological Congress, April 4.20-29, Ankara, Turkey. 土耳其第71届地质大会, 安卡拉, 2018-4-20至2018-4-29
6) Wang Lu, Michael Brown, Andew Klark, Philip Picolli, Changhong Jiang. Adding time to the P-T history of deeply subducted intergranular coesite-bearing eclogite at Yangkou Bay, central Sulu Belt, China. European Geosciences Union General Assembly 2018, Poster
7) On the survival of intergranular coesite from UHP eclogites, Sulu orogen, 2016AGU meeting, SFO, USA. 2016-12-12-2016-12-16. Poster
8) Partial melting of deeply subducted UHP eclogite from Sulu orogen, China, 2015 EGU meeting, Vienna, Austria. Poster
9) Structural Geometry of an Ehumed UHP terrain in the eastern Sulu Orogen, China: Implications for Continental Collisioinal Processes. Eos Trans. 2009 AGU, Fall Meet. Suppl., Abstract V43D-2305, Poster
10) Wang, L., et.al. 2019, A Decade of Research Progress on the Structure, P–T path and Fluid–Melt Evolution of Deeply-Subducted UHP Continental Crust in the Sulu Belt, China, International Symposium on Structural Geology and Tectonics: Links to Lithosphere Evolution and Mantle Dynamics, Karadeniz Technical University, Trabzon, Turkey, April 24-26, 2019. www.generalgeology.com
11) Wang, L., Wang, S.J. Brown, M., Xia, B., Kusky, T.M., Polat, A., Piccoli, P, Johnson, T. 2019, Ten years of Research Progress on the Structure, P–T path and Fluid–Melt Evolution of Deeply-Subducted UHP Continental Crust in the Sulu Belt, DEEP 2018, International Symposium on Deep Earth Exploration and Practices, Oct 24-26, 2018, Chinese Academy of Geological Sciences, National Natural Science Foundation of China, Beijing.
12) Wang, L.et al., 2015, Partially melted UHP eclogite in the Sulu orogenic belt, China, and its rheological significance to deep continental subduction, in: Central Asian Tectonics and Western Pacific Geodynamics, International Conference, State Key Laboratory of Geodesy and Earth’s Dynamics, Institute of Geodesy and Geophysics, Chinese Academy of Sciences, Wuhan China, June 5-7 2015, p. 49.
Students Oral Presentation
1) Chen, Z., Wang L., Brown, M., and Johnson, T.: Changes in deformation mechanism during exhumation of UHP eclogite are related to the presence or absence of supercritical fluid or melt, Sulu belt, China. The Geological society of America 2022 (GSA2022), October 9-12, 2022, Denver, Colorado, USA. Oral presentation (online). doi: 10.1130/abs/2022AM-381624
2) Chen, Z., Wang L., Brown, M., and Johnson, T.: Deformation mechanisms of UHP eclogites during exhumation varies with the presence or absence of supercritical fluid or melt, Taohang, Sulu belt, China. 14th International Eclogite Conference (IEC-14), July 10-13, 2022, Lyon-France. Poster presentation.
3) Feng Peng, Wang L, etc. Slab failure dioritic porphyries derived from two cratons in a continental subduction zone, Sulu orogen, China, American Geophysical Union, Annual Meeting,2022-12
4) Peng Y.Y., Kusky T.M., Wang L. Passive margin-like sequences in amalgamating archipelagos signal continental growth from Archean to present,Geological Society of America, Annual Meeting,2022-10
5) Zhong Y.T., Kusky T., Wang L. Tectonic nappe stacking and crustal architecture in an Archean orogen,Geological Society of America, Annual Meeting,2022-10
6) Zhong YT, Kusky T., Wang L. Tectonic nappe stacking in an Archean suture zone: quantitative structural profile places constraints on orogenic architecture,American Geophysical Union, Annual Meeting,2022-12
7) Ning W.B., Kusky T., Wang L. Operation of modern-style plate tectonics in the Neoarchean: Documentation of Archean eclogite facies oceanic crust in the North China Craton,American Geophysical Union, Annual Meeting,2022-12
8) Hu W. To the transition zone and back: nanolamellae in chromite reveal deep Archean subduction and carbon cycle,American Geophysical Union, Annual Meeting,2022-12
9) Ning W.B, Kusky T., Wang L. Archean eclogite facies oceanic crust indicates modern-style plate tectonics,International Eclogite Conference (IEC) 14th,2022-07
10) Wang, Z., Wang, L., Brown, M., Johnson, T., Partial Melting of Bimineralic Eclogite by Clinopyroxene Breakdown, EGU General Assembly 2021, online, 19–30 Apr 2021, EGU21-14165, https://doi.org/10.5194/egusphere-egu21-14165, 2021. 9
11) Feng Peng,Wang Lu,Michael Brown,Wang Songjie,2018. Age, Composition and Origin of In-Situ Leucosome Pockets in Partially Melted UHP Eclogite from the Sulu Orogen, China. EGU-European Geosciences Union General Assembly 2018.
12) Feng Peng, Wang Lu. Separating multiple episodes of partial melting in polyorogenic crust: An example from the Haiyangsuo complex, northern Sulu belt, eastern China, International Symposium on Granulite Facies Metamorphism and Early Plate Tectonics, Laiyang, Shandong Province, China, Oct. 2018. 麻粒岩相变质作用与早期板块构造国际研讨会, 中国莱阳, 2018-10-20至2018-10-27
13) Feng Peng, Wang L. Multi-phase partial melting in the crust of the composite orogenic belt: taking the Sulu Haiyangsuo terrane as an example, the 2018 Academic Seminar of the 9th metamorphic Professional Committee, Changchun, Jilin Province. 复合造山带地壳内的多期部分熔融:以苏鲁海阳所地体为例, 第九届变质专业委员会2018年学术研讨会, 中国长春, 2018-5-11至2018-5-16
14) Wang Zhenlong. Deformation mechanism and rheological significance of the Sulu partially molten eclogite. Beijing, Oct., 2017, 4th CUG Conference. 王振龙,苏鲁部分熔融榴辉岩的变形机制和流变学意义,2017年10月,北京,中国地球物理协会第4届年会,口头报告
15) Wang Songjie, Excellent students oral presentation. The 16th Annual Academic Conference of the Chinese Society of Mineral and Petro-geochemistry, Xi’an, Shanxi Province, Apr., 2017. 王淞杰,口头报告:“深俯冲陆壳折返过程中变质熔流体形成和演化:以苏鲁造山带复合花岗岩-石英脉研究为例”。 2017年4月陕西西安——中国矿物岩石地球化学学会第16届学术年会,第16届学术年会优秀学生论文
Students Posters
16) Peng Feng, Lu Wang, Timothy Kusky. Slab failure dioritic porphyries derived from two cratons in a continental subduction zone, Sulu orogen, China. AGU22 FALL MEETING, poster.
17) Peng Feng, Lu Wang, Michael Brown, Tim E. Johnson. Melting during decompression of deeply-subducted continental crust: multiple mechanisms and contrasting melt compositions. AGU22 FALL MEETING, poster.
18) Feng Peng,Wang Lu,Michael Brown,Wang Songjie,2017. Multiple episodes of partial melting recorded in the Haiyangsuo complex, northern Sulu belt, eastern China. GSA Annual Meeting
19) Wang Songjie, Wang Lu., Michael Brown. Composite granite-quartz veins in the Sulu belt, China: evidence of supercritical fluid flow during exhumation of deeply subducted UHP continental crust, AGU FALL MEETING, poster, 2016.
20) Wang Songjie, Wang Lu, Michael Brown. Multi-stage barite crystallization in partially melted UHP eclogite from the Sulu belt, China. 2015 EGU meeting, Vienna, Austria.
21) Feng Peng, Wang Lu,2017. Multi-phase melting of rocks in Haiyangsuo area of northern Sulu and its tectonic significance. The 16th Annual Academic Conference of the Chinese Society of Mineral and Petro-geochemistry, Shanxi Province, Apr., 2017北苏鲁海阳所地区岩石的多期熔融及其大地构造意义。矿物岩石地球化学学会第16届学术年会。
22) Feng Peng,Wang Lu, 2016. Two-stage melting of deep subduction continental crust and its tectonic significance: Evidence from light-colored granite veins in North Sulu area., CGU annual meeting, Beijing, 2016. 深俯冲陆壳的两期熔融及其大地构造意义:来自北苏鲁地区浅色花岗岩脉中的证据。中国地球科学联合学术年会。
23) Wang Songjie,Wang Lu., Mike Brown. Crystallization mechanism and indication significance of multistage barite in ultrahigh pressure eclogite in Sulu orogenic belt. The 15th Annual Academic Conference of the Chinese Society of Mineral and Petro-geochemistry, Changchun, Jilin Province, Jun., 2015. 苏鲁造山带超高压榴辉岩中多期重晶石的结晶机制与指示意义,2015年6月,吉林长春——中国矿物岩石地球化学学会第15届学术年会。
Conference and Short-course Organization, international collaboration
1) Sep25-Oct.2nd., CUG, Wuhan, 2013, Short-course (training course, lab thinsection observation and field excursion), Phase-equilibrium, Migmatites, Crustal melting and evolution. Invited: Prof. Wei Chunjing, Michael Brown, Edward Sawyer, Richard White, Simon Wilde. Attendee: 160 people from over 10 universities and institutions.
2) Dec., 2014. Chief executive organizer for 2014 Initiation of Center for Global Tectonics, During 2014 AGU Conference, Dec.15th, SFO, USA, 2014
“First International Meeting of Center for Global Tectonics”, and Reception, Serrano Hotel, San Francisco, Dec. 15 2014. Two hours scientific meeting followed by reception, more than 100 guests.
3) Chief executive organizer for International Symposium on New Theories and Approaches to Global Tectonics and field excursion, Center for Global Tectonics 2nd Meeting, China University of Geosciences, Wuhan, July 1-3, 2015. Visit 1.0Ga Miaowan Ophiolite, Yichang, Hubei Province
4) Nov., Wuhan, 2015. Phase-equilibrium modeling technique. Invited: Prof. Wei Chunjing., Center for Global Tectonics.
5) Chief executive organizer for Tectonics 3rd Annual Meeting and Field Excursion, China University of Geosciences, Wuhan, Chinese Academy of Sciences, Chinese Academy of Geological Sciences, Aug. 27-Sept. 2, 2017. Visit 2.5Ga ophiolitic mélange in Zanhuang domain, Central North China Craton, Xingtai, Hubei Province.
6) Chief executive organizer, Conference on “Onset of Plate Tectonics”, China University of Geosciences, 4th annual meeting of Center for Global Tectonics, Wuhan, June 5, 2021.