崂山国家实验室卓越科学家、德国莱布尼茨科学学会会士、中国地质学会会士、国际冈瓦纳协会副主席、国家自然科学基金创新群体学术带头人、国家杰出青年基金获得者、国家百千万人才工程入选者。现任中国海洋大学海底科学与探测技术教育部重点实验室主任、深海圈层与地球系统教育部前沿科学中心副主任、海洋高等研究院副院长及东华理工大学地球科学学院名誉院长等职务。曾访学于德美日澳的顶级海洋研究机构。现兼任《Geosystems and Geoenvironment》国际期刊主编、《海洋学研究》主编，曾任Science Bulletin、Geoscience Frontiers、Precambrian Research、Gondwana Research等20多个国际国内期刊副主编和编委。

长期从事海洋地质学研究，系统建立了微板块构造理论，创新提出了海底氢能系统。在科学出版社以第一作者或独著出版《微板块构造》《海洋大历史》《海底构造系统》《区域海底构造》《洋底动力学》中文著作13部及“微板块构造”图集4部、在中国海洋大学出版社第一作者出版《海底氢能》1部和主编《星辰大海》科普图集7册等；获得国家发明专利累计15项；在Nature子刊（6篇）、CEE（3篇）、Reviews of Geophysics（1篇）、Geology（4篇）、EPSL（9篇）、Earth-Science Reivews（42篇）、GRL（11篇）、JGR（7篇）、Tectonics（4篇）等发表高质量SCI英文论文500多篇，SCI他引近2万次，多次入选科睿唯安地学领域全球高被引学者，ESI的H指数72。曾获国家自然科学二等奖、李四光地质科学奖科研奖、省部级一二等奖、中国地质学会金锤奖10余项及山东省先进工作者称号。

· 主要代表作如下：

[1]Li, X.H, Ishizuka, O., Stern, R. J., Li, S.Z., Lai, Z.Q., Somerville, I., Suo, Y.H., Chen, L., Yu, H.X.. 2024. A HIMU-like component in Mariana Convergent Margin magma sources during initial arc rifting revealed by melt inclusions. Nature Communications, 15(1): 4088. (corresponding author)
[2]Li, Y.C., Liu, L.J., Li, S.Z., Peng, D.D., Cao, Z.B., Li, X.Y.. 2024. Cenozoic India-Asia collision driven by mantle dragging the cratonic root. Nature Communications, 15(1): 6674. (second corresponding author)
[3]Lu, Z.W., Guo, X.Y., Gao, R., Murphy, M.A., Huang, X.F., Xu, X., Li, S.Z., Li, W.H., Zhao, J.M., Li, C.S., Xiang, B.. 2022. Active construction of southernmost Tibet revealed by deep seismic imaging. Nature Communications, 13: 3143.
[4] Liu, P., Liu, Y.G., Wang, R.M., Li, S.Z., Sun, Y.D., Wen, B., Shen, B.. 2025. Maintenance of the great late Ediacaran ice age. Nature Communications, 16: 3602.
[5] Hu,J., Li, S.Z. , Wang , S,J. , Peckmann, J., Guan, H.X., Jiang, S.Y., Chen, W., Cui, H., Zheng Q., Liu, P., Suo, Y.H., Jiang, Z.X., Li, D.Y., Wang, N., Li, X.H., Zhong, Y., Li, R.R., Yang, X.M., Konhauser, K.O.. 2025. Metal-driven anaerobic oxidation of methane and the Sturtian deglaciation. Nature Communications, 16:7249. (first corresponding author)
[6]Li, X.H., Guo, K., Li, S.Z., Yang, H.X., Pi, J.-L., Zhong, Y., Chen, L., Suo, Y.H., Stern, R. J., Wang, X.Y., Li, D.Y., Yu, S.Y.. 2024. Arc magma heterogeneity induced by subslab mantle upwelling. Geology, 52(12): 870-74. (corresponding author)
[7]Li, X.H., Yan, Q.S., Zeng, Z.G., Fan, J.J., Li, S.Z., Li, J., Yang, H.X., Wang, X.Y.. 2021.Across-arc variations in Mo isotopes and implications for subducted oceanic crust in the source of back-arc basin volcanic rocks. Geology, DOI:10.1130/G48754.1.
[8] Zhong, S.H., Li, S.Z., Liu, Y., Cawood, A.P., Seltamann, R.. 2023. I-type and S-type granites in the Earth’s earliest continental crust. Communications Earth & Environment, 4: 61. (corresponding author)
[9]Chen, L., Wang, Y.Y., Somerville, I., Zhong, Y., Li, X.H., Li, D.Y., Deng, J.H., Yu, S.Y., Sun, G.C., Zhao, Z.F., Li, S.Z.. 2025. Recycled oceanic gabbro produced the depleted component in hotspot magma from the Comei large igneous province in the Kerguelen mantle plume. Communications Earth & Environment, 6(1), 371. (second corresponding author)
[10] Li, X., Zhang, Z., Li, S.Z., Stern, R.J., Ishizuka, O., Yang, H., Suo, Y., Chen, L., Lai, Z., Zhong, Y., Hu, J., Wang, L., Dai, L., Yan, Q., Li, Q.. 2025. Assimilation of upper plate rocks at convergent margins contributes to the low δ18O isotopic signature of erupted magma. Communications Earth & Environment. 6: 515. (second corresponding author)
[11]Li,S.Z., Jahn, B.M., Zhao, S.J., Dai, L.M., Li, X.Y., Suo, Y.H., Guo, L.L., Wang, Y.M., Liu, X.C., Lan, H.Y., Zhou, Z.Z., Zheng, Q.L., Wang, P.C.. 2017. Triassic southeastward subduction of North China Block to South China Block: insights from new geological, geophysical and geochemical data. Earth-Science Reviews,166：270-285.
[12]Li,S.Z., Suo, Y.H., Li, X.Y., Liu, B., Dai L.M., Wang, G.Z., Wang, G., Zhou, J., Li, Y., Liu, Y.M., Cao, X.Z., Somerville, I., Mu, D.L. Zhao, S.J., Liu, J.P., Zhen, L.B., Zhao, L.T., Zhu, J.J., Yu, S.Y., Liu, Y.J., Zhang, G.W.. 2018b. Microplate Tectonics：new insights from micro-blocks in the global oceans, continental margins and deep mantle. Earth-Science Reviews, 185: 1029-1064.
[13]Li,S.Z., Zhao，S.J., Liu, X., Cao, H.H., Yu, S., Li, X.Y., Somerville, I., Yu, S.Y., Suo, Y.H.. 2018a. Closure of the Proto-Tethys Ocean and Early Paleozoic amalgamation of microcontinental blocks in East Asia. Earth-Science Reviews, 186: 37-75.
[14]Li,S.Z., Suo, Y.H., Li, X.Y., Zhou, J., Santosh, M., Wang, P.C., Wang, G.Z., Guo, L.L., Yu, S.Y., Lan, H.Y., Dai, L.M., Zhou, Z.Z., Cao, X.Z., Zhu, J.J., Liu, B., Jiang, S.H., Wang, G., Zhang, G.W.. 2019a. Mesozoic tectono-magmatic evolution in the East Asian ocean-continent connection zone and its relationship with Paleo-Pacific Plate subduction. Earth-Science Reviews, 192: 91-137.
[15]Li, S.Z., Li, X.Y., Wang, G.Z., Liu, Y.M., Wang, ZC., Wang, T.S., Cao, X.Z.，Guo, X.Y., Somerville, I., Li, Y., Zhou, J., Dai, L.M., Jiang, S.H., Zhao, H., Wang, Y., Wang, G., Yu, S., 2019b. Global Meso-Neoproterozoic plate reconstruction and formation mechanism for Precambrian basins: Constraints from three cratons in China. Earth-Science Reviews, 198：102946.
[16]Li, S.Z., Zheng, Y.F., Suo, Y.H.. 2025. Transform fault system: A microplate-based perspective on transform faults. Geological Society of American Bulletin, 198：102946.
[17]Li, S.Z., Zheng, Y.F., Suo, Y.H.. 2025. Reconstructing the framework of the Paleo-Pacific Plate: A synthetic review. Journal of Structural Geology, 199：105505.
[18]Li, S.Z., Dong, Y.P., Chen, H.L.. 2021. Meso-Neoproterozoic proto-basins and oil–gas resources in China: Preface. Precambrian Research, 360: 106221.
[19]Li, S.Z., Zhao, G.C., Santosh, M., Liu, X., Dai, L.M., Suo, Y.H., Tam, P.Y., Song, M.C., Wang, P.C.. 2012. Paleoproterozoic structural evolution of the southern segment of the Jiao-Liao-Ji Belt, North China Craton. Precambrian Research, 200-203: 59-73.
[20]Li, S.Z., Zhao, G.C.. 2007. SHRIMP U-Pb zircon geochronology of the Liaoji Granitoids: constraints on the Paleoproterozoic Jiao-Liao-Ji Belt in the Eastern Block of the North China craton. Precambrian Research, 158(1-2): 1-16.
[21]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, 12(1-2):121-143.
[22]Li, S.Z., Kusky, T.M., Liu, X.C., Zhang, G.W., Zhao, G.C., Wang, L., Wang, Y.J.. 2009. Two-stage collision-related extrusion of the western Dabie HP-UHP metamorphic terranes, central China: evidence from quartz c-axis fabrics and microstructures. Gondwana Research, 16: 294-309.
[23]Li, S.Z.,Zhao, G.C., Zhang, J., Sun, M., Zhang, G.W., Dai, L.M.. 2010. Deformation history of the Hengshan-Wutai-Fuping Mountains: Implications for the evolution of the Trans-North China Orogen. Gondwana Research, 18: 611-631.
[24]Li, S.Z., Zhao, G.C., Sun, M., Luo, Y., Han, Z.Z., Zhao, G.T.. 2006. Are the South and North Liaohe Groups different exotic terranes?—Nd isotope constraints on the Jiao-Liao-Ji Orogen.Gondwana Research, 9:198-208.
[25]Li,S.Z., Geldmacher, J., Hauff, F., Garbe-Schönberg, D., Yu, S., Zhao, S.J., Rausch, S.. 2014. Composition and timing of carbonate vein precipitation within the igneous basement of the Early Cretaceous Shatsky Rise, NW Pacific. Marine Geology, 357: 321-333.
[26]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, 490: 267-293.
[27]Li, S.Z., Kusky, T.M., Zhao, G.C., Liu, X.C., Wang, L., Kopp, H., Hoernle, K., Zhang, G.W., Dai, L.M.. 2011. Thermochronological constraints on Two-stage extrusion of HP/UHP terranes in the Dabie-Sulu orogen, east-central China. Tectonophysics, 504: 25-42.
[28]Li,S.Z., Hu, J.M., Zhu, G., Lin, A.M.. 2015. Active Tectonics and Meso-Cenozoic Intraplate Deformation in North China Block: Preface. Journal of Asian Earth Sciences, 114(Part I): 1-4.
[29]Li,S.Z., Guo, L.L., Xu, L.Q., Somerville, I.D., Cao, X.Z., Yu, S., Wang, P.C., Suo, Y.H., Liu, X., Zhao, S.J., Cao, H.H.. 2015. Coupling and transition of Meso-Cenzoic intraplate deformation between the Taihang and the Qinling Mountains.Journal of Asian Earth Sciences, 114(Part I): 188-202.
[30]Li, S.Z., Zhao, G.C., Sun, M., Han, Z.Z.,Hao, D.F., Luo, Y., Xia, X.P.. 2005. Deformation history of the Paleoproterozoic Liaohe Group in the Eastern Block of the North China Craton. Journal of Asian Earth Sciences, 24(5): 659-674.
[31]Li, S.Z., Zhao, G.C., Dai, L.M., Zhou, L.H., Liu, X., Suo, Y.H., Santosh, M.. 2012. Cenozoic faulting of the Bohai Bay Basin and its bearings on the destruction of the eastern North China Craton. Journal of Asian Earth Sciences, 47: 80-93.
[32]Li, S.Z., Zhao, G.C., Dai, L.M., Liu, X., Zhou, L.H., Santosh, M., Suo, Y.H.. 2012. Mesozoic Basins in eastern China and their Bearings on the deconstruction of the North China Craton. Journal of Asian Earth Sciences, 47: 64-79.
[33]Li, S.Z., Santosh, M., Zhao, G.C., Zhang, G.W., Jin, C.. 2012. Intracontinental deformation in a frontier of super-convergence: A perspective on the tectonic milieu of the South China Block. Journal of Asian Earth Sciecnes, 49: 311-327.
[34]Li, S.Z., Santosh, M., Jahn, B.M.. 2012. Evolution of Asian Continent and its Continental Margins. Journal of Asian Earth Sciences, 47: 1-4.
[35]Li, S.Z., Zhao, G.C., Sun, M.,Wu, F.Y., Liu, J.Z., Hao, D.F., Han, Z.Z., Luo, Y.. 2004. Mesozoic, not Paleoproterozoic SHRIMP U-Pb zircon ages of two Liaoji Granites, eastern block, North China craton. International Geology Review, 46(2):162-176.
[36]Li,S.Z., Suo, Y.H.，Yu, S.Y., Li, R.X., Yang, G.X., Somerville, I.D.. 2017. Central China Orogen along the Silk Road (Part I): Tectono-thermal evolution and its links. Geological Journal, 52(S1):3-7.
[37]Li,S.Z., Suo, Y.H.， Yu, S.Y., Li, R.X., Yang, G.X., Somerville, I.D.. 2018. Central China Orogen along the Silk Road (Part 2): Mineral deposits, hydrocarbons, geohazards, and environments. Geological Journal, 53(S1):4-7.
[38]Li,S.Z., Suo, Y.H.， Li, R.X., Yu, S.Y.,Yang, G.X., Somerville, I.D.. 2018. Tianshan Orogen along the Silk Road (Volume 3): Orogen links, geochemistry, geochronology, mineral deposits, and environments. Geological Journal, 53(S2):3-7.
[39]Li,S.Z., Suo, Y.H.，Santosh，M., Dai，L.M., Yu, S., Zhao, S.J., Jin, C.. 2013. Mesozoic to Cenozoic intracontinental dynamics of the North China Block. Geological Journal, 48(5): 543-560 .
[40]Li, S.Z., Zhao, G.C., Santosh, M., Liu, X., Dai, L.M.. 2011. Palaeoproterozoic Tectono-thermal Evolution and Deep Crustal Processes in the Jiao-Liao-Ji Belt, North China craton: A Review. Geological Journal, 46: 525-543.
[41]Li, S.Z., Zhao, G.C., Zhang, G.W., Liu, X.C., Dai, L.M., Jin, C., Liu, X., Hao, Y., Liu, E.S., Wang, T.. 2010. Not All Folds and Thrusts in the Yangtze Foreland Belt are related to the Dabie-Sulu Orogen: Insights from Mesozoic Deformation South of the Yangtze River. Geological Journal, 44: 1-13.
[42]Li, S.Z., Kusky, T.M., Zhao, G.C., Wu, F.Y., Liu, J.Z., Wang, L., Sun, M., 2007. Mesozoic tectonics in the Eastern Block of the North China Craton: implications for subduction of the Pacific Plate beneath the Eurasian Plate. Mesozoic Sub-Continental Lithoshperic Thinning Under Eastern Asia. Edited by Mingguo Zhai，Brian F. Windley，Timothy M. Kusky and Qingren Meng. Geological Society, London, Special Publications, 280: 171-180.
[43]Li, S.Z., Li, G.X., Liu, X., Somerville, I.. 2016. Preface: Earth system evolution of the Pacific and Indian oceans and the South China Sea. Geological Journal, 51(S1): 5-11.
[44]Li, S.Z., Yu, S., Suo, Y.H., Wu, T.T., Somerville, I., Sager, W., Li, X.Y., Hui, G.G., Zhang, Y., Zang, Y.B., Zheng, Q.L.. 2016. Orientation of joints and arrangement of solid inclusions in fibrous veins in the Shatsky Rise, NW Pacific: implications for crack-seal mechanisms and stress fields. Geological Journal, 51(S1): 562-578.
[45]Jiang, Z.X., Li, S.Z., Liu, Q.S., Zhang, J.L., Zhou, Z.Z., Zhang, Y.Z.. 2021. The trials and tribulations of the Hawaii hot spot model. Earth-Science Reviews, 215: 103544.
[46]Zhao, F.Y., Li, S.Z., Jiang, S.H., Liu, L.J., Zhu, J.J., Dai, M.X., Liu, Y., Wang, G., Liu, Z., Hu, B., Zhu, Y.X.. 2023. Transcurrent tectonic system and deep seismogenic mechanism in the southeastern Tibetan Plateau: A view from gravity and magnetic anomalies. Earth-Science Reviews, 236(6): 104269.
[47] Suo, Y.H., Li, S.Z., Cao, X.Z., Wang, X.Y., Somerville, I., Wang, G.Z., Wang, P.C., Liu, B. 2020. Mesozoic-Cenozoic basin inversion and geodynamics in East China: A review. Earth-Science Reviews 210, 103357.
[48]Suo, Y.H., Li, S.Z., Jin, C., Zhang, Y., Zhou, J., Li, X.Y., Wang, P.C., Liu, Z., Wang, XY., Somerville, I., 2019. Eastward tectonic migration and transition of the Jurassic-Cretaceous Andean-type continental margin along Southeast China. Earth-Science Reviews,196, 102884.
[49]Suo, Y.H., Li, S.Z., Cao, X.Z., Liu, Y.M., Zhu, J.J., Li, X.Y., Somerville, I.. 2021. Mantle micro-block beneath the Indian Ocean and its implications on the continental rift-drift-collision of the Tethyan evolution. Earth-Science Reviews, 217: 103622.
[50]Zhong, S.H., Li, S.Z., Feng, C.Y., Liu, Y.J., Santosh, M., He, S.Y., Qu, H.Y., Liu, G.Y., Reimar, S., Lai, Z.Q., Wang, X.H., Song, Y.X., Zhou, J.. 2021. Porphyry copper and skarn fertility of the northern Qinghai-Tibet Plateau collisional granitoids. Earth-Science Reviews, 214: 103524.
[51]Wang, P.C., Li, S.Z., Suo, Y.H., Guo, L.L., Santosh, M., Li, X.Y., Wang, G.Z., Jiang, Z.X., Liu, B., Zhou, J., Jiang, S.H., Cao, X.Z., Liu, Z.. 2021. Structural and kinematic analysis of Cenozoic rift basins in South China Sea: A synthesis. Earth-Science Reviews, 216: 103522.
[52]Dai, L.M., Li, S.Z., Liu, Z., Hu, M.Y., Ma, F.F., Tao, J.L.. 2018. Dynamic process and mechanism for post-orogenic extension in the West Dabie Orogen. Earth-Science Reviews, 182: 68-84.
[53]Liu, Y.M., Li, S.Z., Santosh, M., Cao, H.H., Yu, S.Y., Wang, Y.H., Zhou, J., Zhou, Z.Z., 2019. The generation and reworking of continental crust during early Paleozoic in Gondwanan affinity terranes from the Tibet Plateau. Earth-Science Reviews, 190, 486-497.
[54]Yu, S.Y., Li, S.Z., Zhang, J.X., Peng, Y.B., Somerville, I., Liu, Y.J., Wang, Z.Y., Li, Z.F., Yao, Y., Li, Y., 2019. Multistage anatexis during tectonic evolution from oceanic subduction to continental collision: A review of the North Qaidam UHP Belt, NW China. Earth-Science Reviews, 191, 190-211.
[55] Zhu, J., Li, S.Z., Jia, Y., Zhang, S., Chen, X., Chen, R., Suo, Y., Cao, X., Jia, Z., Ou, X., Liu, J., Wang, P., Zhou, J.. 2022. Links of high velocity anomalies in the mantle to the Proto-South China Sea slabs: Tomography-based review and perspective, Earth-Science Reviews, 231, 104074.
[56]Cao, X.Z., Flament, N., Li, S.Z., Müller, R. D.. 2021. Spatio-temporal evolution and dynamic origin of Jurassic-Cretaceous magmatism in the South China Block. Earth-Science Reviews, 217 :103605.
[57]Liu, Z., Dai, L.M., Li, S.Z., Wang, L.L., Xing, H.L., Liu, Y.J., Ma, F.F., Dong, H., Li, F.K.. 2021. When plateau meets subduction zone: A review of numerical models. Earth-Science Reviews, 215:103556.
[58]Peng, Y.B., Yu, S.Y., Li, S.Z., Zhang, J.X., Liu, Y.J., Li, Y.S., Santosh, M., 2019. Early Neoproterozoic magmatic imprints in the Altun-Qilian-Kunlun region of the Qinghai-Tibet Plateau: Response to the assembly and breakup of Rodinia supercontinent, Earth-Science Reviews,https://doi.org/10.1016/j.earscirev.2019.102954.
[59] Peng, Y.B., Yu,S.Y., Li, S.Z., Liu, Y.J., Santosh, M., Lv, P., Li, Y.S., Xie, W.M., Liu, Y.M.. 2020. The odyssey of Tibetan Plateau accretion prior to Cenozoic India-Asia collision: Probing the Mesozoic tectonic evolution of the Bangong-Nujiang Suture. Earth-Science Reviews, 211, 103376.
[60]Zhao, G.C., Sun, M., Wilde, S.A., Li, S.Z., 2004. A paleo-mesoproterozoic supercontinent: assembly, growth and breakup. Earth-Science Reviews, 67: 91-123
[61] Di, Q.Y., Tian, F., Suo, Y.H., Gao, R., Li, S.Z., Fu, C.M., Wang, G.Z., Li, F., Tan, Y.Y..2021. Linkage of deep lithospheric structures to intraplate earthquakes: A perspective from multi-source and multi-scale geophysical data in the South China Block. Earth-Science Reviews, 214 :103504.
[62] Yu, S.Y., Peng, Y.B., Zhang, J.X., Li, S.Z., Santosh, M., Li, Y.S., Liu, Y.J., Gao, X.Y., Ji, W.T., Lv, P., Li, C.Z., Jiang, X.Z., Qi, L.L., Xie, W.M., Xu, L.J.. 2021. Tectono-thermal evolution of the Qilian orogenic system: Tracing the subduction, accretion and closure of the Proto-Tethys Ocean. Earth-Science Reviews, 215: 103547.
[63]Jiang, S.H., Jiang, Y., Liu, Y.M., Li, S.Z., Zhang, W., Wang, G., Lu, L.L., Somerville, I.. 2021. The Bangong-Nujiang Suture Zone, Tibet Plateau: Its role in the tectonic evolution of the eastern Tethys Ocean. Earth-Science Reviews, 218: 103656.
[64]Zhao, G.C., Wang, Y.J., Huang, B.C., Dong, Y.P., Li, S.Z., Zhang, G.W., Yu, S., 2018. Geological reconstructions of the East Asian blocks: From the breakup of Rodinia to the assembly of Pangea. Earth-Science Reviews, 186, 262-286.
[65]Zhao, F.Y., Suo, Y.H., Liu, L.J., Cao, X.Z., Li, S.Z., Jiang, S.H., Deng, J.Z., Dai, M.X., Liu, Y., Hu, Y.P., Sheng, S.Z., Hu, B.. 2023. Fine lithospheric structure controlling Meso-Cenozoic tectono-magmatism in the South China Block: Inference from a multidisciplinary analysis. Earth-Science Reviews, 244: 104524.
[66]Liu, L,J., Peng, D.D., Liu, L., Chen, L., Li, S.Z., Wang, Y.Y., Cao, Z.B., Feng, M.Y.. 2021. East Asian lithospheric evolution dictated by multistage Mesozoic flat-slab subduction. Earth-Science Reviews, 217:103621.
[67]Zhang, C.M., Sun, Z., Gianreto, M., Pang, X., Li, S.Z., Daniel, S., Gwenn, P., Zhao, M.H.. 2021. Ocean-continent transition architecture and breakup mechanism at the mid-northern South China Sea. Earth-Science Reviews, 217:103620.
[68]Li, J.B., Ding, W.W., Lin, J., Xu, Y.G., Kong, F.S., Li, S.Z., Huang, X.L., Zhou, Z.Y.. 2021. Dynamic processes of the curved subduction system in Southeast Asia: A review and future perspective. Earth-Science Reviews, 217:103647.
[69] Zhou, T., Liu, Y.J., Guan, Q.B., Liu, B.R., Xiao, W.J., Li, S.Z., Chen, Z.X., Peskov, A. Yu.. 2025. Tectonic evolution of the eastern Central Asian Orogenic Belt during the Carboniferous–Permian. Earth-Science Reviews, 267, 105046.
[70] Liu, Y.J., Li, W.M., Ma, Y.F., Feng, Z.Q., Guan, Q.B., Li,S.Z., Chen, Z.X., Liang, C.Y., Wen,Q.B.. 2021. An orocline in the eastern Central Asian Orogenic Belt. Earth-Science Reviews, 221, 103808.
[71]Cui, Y.C., Shao, L., Li, Z.-X., Elders, C., Stattegger, K., Zhu, W.L., Li, S.Z., Zhao, X.X., Qiao, P.J., Zhang, H.. 2024. Early Cenozoic drainage network and paleogeographic evolution within the SE Tibetan Plateau and its surrounding area: Synthetic constraints from onshore-offshore geological dataset. Earth-Science Reviews, 258: 104932.
[72]Wang, G., Jiang, S.H., Wang, P.C., Guo, L.L., Jiang, Y., Lu, L.L., Somerville, I., Li, S.Z.. 2021. Mesozoic subduction-related accretion of micro-blocks in the East Asian Ocean-Continent Connection Zone. Earth-Science Reviews, 216:103575 (SCI).
[73]Zhao, G.C., Sun, M., Wilde, S.A., Li S.Z., 2005. Late Archean to Paleoproterozoic evolution of the North China Craton: key issues revisited. Precambrian Research, 136：177-202
[74] Suo, Y.H., Li, S.Z., Cao, X.Z. 2020. Large-scale asymmetry in thickness of crustal accretion at the Southeast Indian Ridge due to deep mantle anomalies. Geological Society of American Bulletin, DOI:10.1130/B35673.1.
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