- 姓名: 李鹏飞
- 性别: 男
- 职务:
- 职称: 研究员
- 学历: 博士研究生
- 电话: 85290121
- 传真:
- 电子邮件: pengfeili@gig.ac.cn
- 通讯地址: 广州市天河区科华街511号
李鹏飞,研究员,博士生导师,2007年和2009年分别获东北大学本科及硕士学位,2013年获澳大利亚昆士兰大学构造地质学/大地构造学博士学位,曾在香港大学地球科学系从事博士后研究工作,国家海外高层次人才计划入选者,德国洪堡学者,2017年至今在广州地球化学研究所工作。主要从事造山带大地构造学研究,取得的主要研究成果包括:1)厘定了澳洲东部新英格兰山弯构造耳朵形几何形态,提出俯冲带不均匀后撤导致该山弯构造形成的动力学模式;2)重建了南西太平洋地区晚古生代-中生代构造格局,揭示了汇聚板块边缘地体裂解与俯冲带后撤的成因联系;3)从古亚洲洋闭合时限的角度,揭示了中亚哈萨克斯坦山弯构造的同俯冲成因;4)确立了阿尔泰造山带与东西准噶尔地体的汇聚历史,揭示了汇聚板块边缘地体碰撞拼贴的动力学演化过程。近期的研究内容主要包括:(1)山弯构造形成机制与造山带4D重建;(2)中亚造山带多岛洋构造体系形成与弧弧碰撞拼贴动力学过程;(3)喜马拉雅造山过程与机制;(4)古南海形成演化与东南亚构造重建。
招生:
长期招聘有志于固体地球科学研究的硕士生、博士生、博士后、助理研究员以及副研究员。尤其欢迎具有构造地质学、变质岩石学、低温热年代学、热动力学/热运动学模拟等背景的博士毕业生来进行博士后合作研究。
与以下单位建立了良好的国际合作关系:澳大利亚昆士兰大学、澳大利亚科廷大学、香港大学、德国图宾根大学、瑞士伯尔尼大学
国际合作: 学术服务:欧洲地球科学联合会年会(EGU2016, 2019)、亚洲大洋洲地球科学联合会(AOGS 2013)、中国地球科学联合会(CGU 2019)、构造地质与地球动力学青年论坛(2018-2019)等会议专题召集人。
国际期刊审稿:Geology, Journal of Geophysical Research-Solid Earth, Journal of Structural Geology, Journal of Virtual Explorer, Solid Earth (EGU), Gondwana Research, Australian Journal of Earth Sciences, Precambrian Research, Journal of Asian Earth Sciences, Tectonophysics, International Geology Review, China Science, Geoscience Frontier, International Journal of Earth Sciences, Geophysical Journal International
简 历:
社会任职:
造山带大地构造学(澳洲东部Tasmanides、中亚造山带、东喜马拉雅)
岩石变形机制与显微构造学
构造热年代学(40Ar/39Ar; FT; (U-Th)/He)
研究方向:
2017年:国家海外高层次人才项目
2012年:国家优秀自费留学生奖
2012年:澳大利亚昆士兰大学Donald Tugby奖
获奖及荣誉:
38. Li, P., Sun, M., Narantsetseg, T., Jourdan, F., Hu, W., Yuan, C., 2022, First structural observation around the hinge of the Mongolian Orocline (Central Asia): implications for the geodynamics of oroclinal bending and the evolution of the Mongol-Okhotsk Ocean, Geological Society of America Bulletin, in press
37. Hu, W., Li, P., Sun, M., Safonova, I., Jiang, Y., Yuan, C., Kotler, P., 2022. Provenance of late Paleozoic sedimentary rocks in eastern Kazakhstan: Implications for the collision of the Siberian margin with the Kazakhstan collage. Journal of Asian Earth Sciences, 104978. (研究生第一作者)
36. Jiang, Y., ?t psk , P., Schulmann, K., Aguilar, C., Wang, S., Anczkiewicz, R., Zhang, J., Li, P., Chopin, F., 2022. Barrovian and Buchan metamorphic series in the Chinese Altai: P–T–t–D evolution and tectonic implications. Journal of Metamorphic Geology, in press.
35. Li, P., Sun, M., Yuan, C., Jourdan, F., Hu, W., Jiang, Y., 2021. Late Paleozoic tectonic transition from subduction to collision in the Chinese Altai and Tianshan (Central Asia): new geochronological constraints. American Journal of Science 321, 178-205.
34. Ling, J., Li, P., Yuan, C., Sun, M., Zhang, Y., Narantsetseg, T., Wang, X., Jiang, Y., Hu, W., 2021. Ordovician to Devonian granitic plutons in the Hangay Range, Central Mongolia: Petrogenesis and insights into the Paleozoic tectonic evolution of the westernmost Mongol-Okhotsk Orogen. LITHOS 404-405, 106463. (研究生第一作者)
33. He, L., Sun, X., Li, P., Ai, S., Li, J. Lithospheric structure near Jiuyishan, South China: implications for asthenospheric upwelling and lithospheric modification, in revision, Geophysical Research Letter.
32. Wang, S., Jiang, Y., Weinberg, R., Schulmann, K., Zhang, J., Li, P., Xiao, M., Xia, X.-P., 2021. Flow of Devonian anatectic crust in the accretionary Altai Orogenic Belt, central Asia: Insights into horizontal and vertical magma transfer. GSA Bulletin.
31. Zhang, Y., Yuan, C., Sun, M., Huang, Z., Narantsetseg, T., Ren, Z., Li, P., Zhang, Q., 2021. Contrasting compositions between phenocrystic and xenocrystic olivines in the Cenozoic basalts from central Mongolia: Constraints on source lithology and regional uplift. American Mineralogist 106, 251-264.
30. Kotler, P., Khromykh, S., Kruk, N., Sun, M., Li, P., Khubanov, V., Semenova, D., Vladimirov, A., 2021. Granitoids of the Kalba batholith, Eastern Kazakhstan: U–Pb zircon age, petrogenesis and tectonic implications. LITHOS 388-389, 106056.
29. Zhang, Y., Li, P., Sun, M., and Yuan, C. (2020), Late Paleozoic to early Triassic granitoids from the Rudny Altai, Central Asian Orogenic Belt: Petrogenesis and implications for continental crustal evolution, Solid Earth Sciences 5, 115-129.
28. Hu, W., Li, P., Rosenbaum, G., Liu, J., Jourdan, F., Jiang, Y., Wu, D., Zhang, J., Yuan, C., and Sun, M., 2020, Structural evolution of the eastern segment of the Irtysh Shear Zone: Implications for the collision between the East Junggar Terrane and the Chinese Altai Orogen (northwestern China): Journal of Structural Geology, v. 139, p. 104126. (研究生第一作者).
27. Li, P., Sun, M., Rosenbaum, G., Cai, K., Yuan, C., Jourdan, F., Xia, X., Jiang, Y., Zhang, Y., 2020. Tectonic evolution of the Chinese Tianshan Orogen from subduction to arc-continent collision: Insight from polyphase deformation along the Gangou section, Central Asia. Geological Society of America Bulletin, 132, 2529-2552.
26. Huang, Y., Jiang, Y., Collett, S., Wang, S., Xu, K., Shu, T., Li, P., Yuan, C., 2020. Magmatic recycling of accretionary wedge: A new perspective on Silurian-Devonian I-type granitoids generation in the Chinese Altai. Gondwana Research 78, 291-307.
25. Zhang, Y., Yuan, C., Sun, M., Long, X., Huang, Z., Jiang, Y., Li, P., Du, L., 2020. Two late Carboniferous belts of Nb-enriched mafic magmatism in the Eastern Tianshan: Heterogeneous mantle sources and geodynamic implications. Geological Society of America Bulletin 5, 115-129
24. Li, P., Sun, M., Shu, C., Yuan, C., Jiang, Y., Zhang, L., Cai, K., 2019. Evolution of the Central Asian Orogenic Belt along the Siberian margin from Neoproterozoic-Early Paleozoic accretion to Devonian trench retreat and a comparison with Phanerozoic eastern Australia. Earth-Science Reviews 198, 102951.
23. Zhang, Y., Yuan, C., Sun, M., Chen, M., Hong, L., Li, J., Long, X., Li, P., Lin, Z., 2019. Recycled oceanic crust in the form of pyroxenite contributing to the Cenozoic continental basalts in central Asia: new perspectives from olivine chemistry and whole-rock B–Mo isotopes. Contributions to Mineralogy and Petrology 174, 83.
22. Chen, M., Sun, M., Li, P., Zheng, J., Cai, K., and Su, Y., 2019, Late Paleozoic Accretionary and Collisional Processes along the Southern Peri-Siberian Orogenic System: New Constraints from Amphibolites within the Irtysh Complex of Chinese Altai, The Journal of Geology, 127, 241-262.
21. Jiang, Y., Schulmann, K., Sun, M., Weinberg, R., ?t psk , P., Li, P., Zhang, J., Chopin, F., Wang, S., Xia, X., and Xiao, W., 2019, Structural and Geochronological Constraints on Devonian Suprasubduction Tectonic Switching and Permian Collisional Dynamics in the Chinese Altai, Central Asia: Tectonics 38, 253-280.
20. Zhang, Y., Sun, M., Yuan, C., Long, X., Jiang, Y., Li, P., Huang, Z., and Du, L., 2018, Alternating Trench Advance and Retreat: Insights From Paleozoic Magmatism in the Eastern Tianshan, Central Asian Orogenic Belt, Tectonics 37, 2142-2164.
19. Li, P., Sun, M., Rosenbaum, G., Yuan, C., Safonova, I., Cai, K., Jiang, Y., and Zhang, Y., 2018, Geometry, kinematics and tectonic models of the Kazakhstan Orocline, Central Asian Orogenic Belt, Journal of Asian Earth Sciences 153, 42-56.
18. Li, P., Sun, M., Rosenbaum, G., Jourdan, F., Li, S., Cai, K., 2017. Late Paleozoic closure of the Ob-Zaisan Ocean along the Irtysh Shear Zone (NW China), Central Asian Orogenic Belt. Geological Society of American Bulletin 129, 547-569.
17. Yu, Y., Sun, M., Huang, X.-L., Zhao, G., Li, P., Long, X., Cai, K., and Xia, X., 2017, Sr-Nd-Hf-Pb isotopic evidence for modification of the Devonian lithospheric mantle beneath the Chinese Altai, Lithos 284–285, 207-221.
16. Yu, Y., Sun, M., Long, X., Li, P., Zhao, G., Kr?ner, A., Broussolle, A., and Yang, J., 2016, Whole-rock Nd–Hf isotopic study of I-type and peraluminous granitic rocks from the Chinese Altai: Constraints on the nature of the lower crust and tectonic setting: Gondwana Research 47, 131–141.
15. Li, P., Sun, M., Rosenbaum, G., Cai, K. Chen, M., He, Y., 2016. Transpressional deformation, strain partitioning and fold superimposition in the southern Chinese Altai, Central Asian Orogenic Belt, Journal of Structural Geology, 87, 64-80.
14. Li, P., Sun, M., Rosenbaum, G., Jiang, Y., Cai, K., 2016. Structural evolution of zonal metamorphic sequences in the southern Chinese Altai and relationships to Permian transpressional tectonics in the Central Asian Orogenic Belt. Tectonophysics, doi: 10.1016/j.tecto.2015.11.035
13. Wang, G.-G., Ni, P., Zhao, C., Wang, X.-L., Li, P., Chen, H., Zhu, A.-D., Li, L., 2016. Spatiotemporal reconstruction of Late Mesozoic silicic large igneous province and related epithermal mineralization in South China: Insights from the Zhilingtou volcanic-intrusive complex. Journal of Geophysical Research: Solid Earth 121, 7903-7928.
12. Li, P., Rosenbaum, G., Yang, J-H, Hoy, D., 2015. Australian-derived detrital zircons in the Permian-Triassic Gympie terrane (eastern Australia): evidence for an autochthonous origin. Tectonics 34, doi:10.1002/2015TC003829.
11. Li, P., Sun, M., Rosenbaum, G., Cai, K., Yu, Y., 2015. Structural evolution of the Irtysh Shear Zone (northwestern China) and implications for the amalgamation of arc systems in the Central Asian Orogenic Belt. Journal of Structural Geology 80, 142-156.
10. Li, P., Rosenbaum, G., 2015. Reply to comment by Offler et al. on “Does the Manning orocline exist? New structural evidence from the inner hinge of the Manning Orocline (eastern Australia)”. Gondwana Research 27, 1689-1691, doi: http://dx.doi.org/10.1016/j.gr.2014.03.002.
9. Li, P., Yuan, C., Sun, M., Long, X, Cai, K, 2015, Thermochronological constraints on the late Paleozoic tectonic evolution of the southern Chinese Altai, Journal of Asian Earth Science 113, 51-60.
8. He, Y., Sun, M., Cai, K., Xiao, W., Zhao, G., Long, X., Li, P., 2015. Petrogenesis of the Devonian High-Mg rock association and its tectonic implication for the Chinese Altai orogenic belt, NW China. Journal of Asian Earth Sciences 113, 61-74.
7. Li, P., Rosenbaum, G. and Vasconcelos, P., 2014, Chronological constraints on the Permian geodynamic evolution of eastern Australia, Tectonophysics 617, 20-30.
6. Li, P., Rosenbaum, G., 2014. Does the Manning Orocline exist? New structural evidence from the inner hinge of the Manning Orocline (eastern Australia). Gondwana Research 25, 1599-1613.
5. Shaanan, U., Rosenbaum, G., Li, P., Vasconcelos, P., 2014. Structural evolution of the early Permian Nambucca Block (New England Orogen, eastern Australia) and implications for oroclinal bending. Tectonics 33, doi:10.1002/2013TC003426.
4. Wang, G.-G., Ni, P., Yu, W., Chen, H., Jiang, L.-L., Wang, B.-H., Zhang, H.-D., Li, P.-F., 2014. Petrogenesis of Early Cretaceous post-collisional granitoids at Shapinggou, Dabie Orogen: Implications for crustal architecture and porphyry Mo mineralization. Lithos 184–187, 393-415.
3. Li, P., Rosenbaum, G. and Donchak P.J.T., 2012. Structural evolution of the Texas Orocline, eastern Australia, Gondwana Research 22, 279-289.
2. Li, P., Rosenbaum, G. and Rubatto, D., 2012, Triassic asymmetric subduction rollback in the southern New England Orogen (eastern Australia): the end of the Hunter-Bowen orogeny, Australian Journal of Earth Sciences 59, 965-981.
1. Rosenbaum, G. Li, P. and Rubatto, D., 2012. The contorted New England Orogen (eastern Australia): new evidence from U-Pb geochronology of early Permian granitoids, Tectonics 31, doi:10.1029/2011TC002960