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姓名 胡方泱 性别:
职称 特聘副研究员 学位 博士
电话 传真: 010-62010846
Email: hufangyang[a]mail.iggcas.ac.cn 邮编: 100029
地址 北京朝阳区北土城西路19号,中科院地质与地球物理研究所
更多信息:

English岩石圈演化与环境演变全国重点实验室矿产资源学科中心 关键金属成矿作用学科组
 
简历:

  胡方泱,男,1991年9月生。主要从事碰撞造山带花岗质岩浆作用与造山带演化及相关稀有金属成矿研究。主要研究手段包括岩石地球化学、地质年代学和大数据统计分析等。目前主要关注青藏高原东缘和南缘花岗质岩浆作用与相关稀有金属成矿。发表论文60余篇,其中第一作者/通讯作者SCI论文17篇,主要发表在NC、EPSL、GRL和JP等国际主流刊物。主要学术成果包括:(1)发现岛弧岩浆氧逸度具有随纬度变化的特征,提出太阳辐射对于地表环境的纬度效应可以随大洋俯冲作用从而影响岛弧地幔的氧逸度;(2)建立了利用岩浆岩地球化学比值定量计算碰撞带地壳厚度及岛弧带和碰撞带海拔高度的方法,重建了秦岭中生代地壳厚度演化历史及青藏高原白垩纪-新生代古高度演化历史;(3)论证青藏高原东缘新生代时期不存在大规模地壳流;(4)提出高地温梯度可以有效延长岩浆演化时间、增加沉积岩混染效率,促进岩浆高分异过程和锂的超常富集;(5)论证了秦岭早中生代岩浆作用峰期与大洋板片单向断离有关,提出了华南与华北板块早中生代4阶段斜向碰撞造山模型。

学习和工作经历:
  2013年本科毕业于中国地质大学(武汉)
  2018年博士毕业于北京大学
  2016年9月-2017年8月公派赴美国亚利桑那大学访问1年
  2018年7月-2021年1月于中国科学院地质与地球物理研究所从事博士后研究工作
  2021年1月起任中国科学院地质与地球物理研究所特聘副研究员

学术任职:
  Geological Society of America Bulletin 副主编 (2024-2026)
  中国地质                青年编委(2024-2026)
 
学科类别:
地质学,地球化学
 
研究方向:
  1. 花岗质岩石成因机制
  2. 岩浆作用与造山带演化
  3. 碰撞带岩浆作用与稀有金属成矿
 
职务:
 
社会任职:
 
承担科研项目情况:
  1. 国家重点研发计划项目子课题(2024YFC2909304),喜马拉雅铌钽铷铯成矿过程与潜力评价,2024.12-2027.11,参与
  2. 国家自然科学基金基础科学中心项目(42888201),大陆演化与季风系统演变,2024.04-2028.12,参与
  3. 中国科学院先导A类项目(XDA0430101),喜马拉雅成矿带伟晶岩型锂矿带资源潜力,2023.10-2028.09,参与
  4. 国家自然科学基金重大研究计划(92255303),特提斯地球动力系统集成(一期),2023.01-2026.12,参与
  5. 第二次青藏高原综合科学考察研究(2022QZKK0200),铷铯资源现状与远景评估,2022.10-2025.09,参与
  6. 国家自然科学基金青年项目(41902055),青藏高原东缘贡嘎山-折多山花岗质侵入杂岩的成因:对地壳流的指示意义,2020.01-2022.12,主持
  7. 第二次青藏高原综合科学考察研究(2019QZKK0802),稀有金属资源现状与远景评估,2019.01-2024.10,参与
  8. 博士后基金面上项目(2018M640177),岩浆岩地球化学指标与造山带海拔高度的相关关系及应用,2018.12-2021.01,主持
 
获奖及荣誉:
  1. 2024年度研究所优秀科技成果(2/5)
  2. 2018年第九届李四光优秀博士研究生奖
  3. 2018年北京大学优秀毕业生
  4. 博士研究生国家奖学金
  5. 2017年北京大学创新奖(学术类)
  6. 2016年博士研究生国家奖学金
 
代表论著:

Google Scholar

第一作者及通讯作者文章:

*通讯作者

1. Hu, F.*, Ducea, M. N., Chapman, J. B.,   Yang, L., Chen, G., Guo, C., Wu, F. Y. 2025. High geothermal gradients   facilitating lithium mineralization: Insights from the Ke’eryin–Taiyanghe   plutons, central China. Earth and Planetary Science Letters, 672, 119693.

2. 段小丫, 胡方泱*, 张少华, 封占江, 梁永, 刘延虎, 王志强, 李海宝, 燕轶男.   2025. 华北克拉通北缘三木代庙地区花岗岩与伟晶岩石英微量元素成分特征及其对高纯石英成因的指示. 岩石学报, 41(10), 3432-3452.

3. Hu, F.*, Jiang, H., Wan, B., Ducea,   Mihai N., Gao, L., Wu, F. Y. 2024. Latitude-dependent oxygen fugacity in arc   magmas. Nature Communications 15, 6050.

4. 胡方泱*, 蒲浩澜, 郭钊, 刘谭杰, 刘小驰, 何少雄, 吴福元. 2024. 希夏邦马峰地区岗布锂辉石伟晶岩的发现及其指示意义. 岩石学报 40(05), 1489-1509.

5. 胡方泱*, 杨雷, 陈国辉, 吴福元. 2024. 锆石微量元素示踪锂成矿岩浆-热液演化过程. 地质学报 98(05), 1615-1636.

6. Hu, F.*, Liu, X., He, S., Wang, J., Wu,   F. 2023. Cesium-rubidium mineralization in Himalayan leucogranites. Science   China Earth Sciences 66(12), 2827-2852. (胡方泱*, 刘小驰, 何少雄, 王佳敏, 吴福元. 2023. 喜马拉雅淡色花岗岩铷铯成矿作用. 中国科学: 地球科学   53(12), 2868-2895.)

7. Chen, G., Hu, F.*, Robertson, A. H., Garzanti, E., Zhang,   S., Wu, F. Y. 2023. A combined methodology for reconstructing source-to-sink   basin evolution, exemplified by the Triassic Songpan–Ganzi basin, central   China. Sedimentary Geology 458, 106529.

8. Hu, F.*, Wu, F. Y., Ducea, M. N.,   Chapman, J. B., Yang, L. 2022. Does Large‐Scale   Crustal Flow Shape the Eastern Margin of the Tibetan Plateau? Insights From   Episodic Magmatism of Gongga‐Zheduo Granitic Massif.   Geophysical Research Letters 49(12), e2022GL098756.

9. Hu, F.*, Wu, F. Y., Wang, J. G., Ducea,   M. N., Chapman, J. B., Zaw, K., Lin, W., Sein, K, Meffre, S. 2022. Newly   discovered Early Carboniferous and Late Permian magmatic rocks in eastern   Myanmar: Implications for the tectonic evolution of the eastern Paleo-Tethys.   Journal of Asian Earth Sciences 227, 105093.

10. 胡方泱*, 吴福元, 陈国辉, 杨雷. 2022. 花岗-伟晶岩型锂矿床围岩变质沉积岩中锂富集的关键因素:以松潘-甘孜构造带东部可尔因地区为例. 岩石学报 38(07), 2017-2051.

11. Hu, F.*, Wu, F.Y., Chapman, J.B., Ducea,   M.N., Ji, W., Liu, S., 2020. Quantitatively Tracking the Elevation of the   Tibetan Plateau Since the Cretaceous: Insights from Whole-Rock Sr/Y and La/Yb   Ratios. Geophysical Research Letters 47, e2020GL089202.

12. Hu, F., Liu, S.*, Ducea, M.N., Chapman,   J.B., Wu, F.Y., Kusky, T., 2020. Early Mesozoic magmatism and tectonic   evolution of the Qinling Orogen: Implications for oblique continental   collision. Gondwana Research 88, 296–332.

13. Hu, F., Liu, S.*, Ducea, M.N., Zhang,   W., Chapman, J.B., Fu, J., Wang, M., 2018. Interaction Among Magmas from   Various Sources and Crustal Melting Processes During Continental Collision:   Insights from the Huayang Intrusive Complex of the South Qinling Belt, China.   Journal of Petrology 59, 735–770.

14. Hu, F., Liu, S.*, Ducea, M.N., Zhang,   W., Deng, Z., 2017. The geochemical evolution of the granitoid rocks in the   South Qinling Belt: Insights from the Dongjiangkou and Zhashui intrusions,   central China. Lithos 278–281, 195–214.

15. Hu, F., Ducea, M.N., Liu, S.*, Chapman,   J.B., 2017. Quantifying Crustal Thickness in Continental Collisional Belts:   Global Perspective and a Geologic Application. Scientific reports 7, 7058.

16. Hu, F., Liu, S.*, Santosh, M., Deng, Z.,   Wang, W., Zhang, W., Yan, M., 2016. Chronology and tectonic implications of   Neoproterozoic blocks in the South Qinling Orogenic Belt, Central China.   Gondwana Research 30, 24–47.

17. Hu, F., Liu, S.*, Zhang, W., Deng, Z.,   Chen, X., 2016. A westward propagating slab tear model for Late Triassic   Qinling Orogenic Belt geodynamic evolution: Insights from the petrogenesis of   the Caoping and Shahewan intrusions, central China. Lithos 262, 486–506.

合作文章:

1. 吴福元, 徐家辉, 张门品, 杨岳衡, 胡方泱, 杨浩, 彭澎. 2026. 华北克拉通早前寒武纪稀有金属成矿作用. 岩石学报, 42(1): 1-37.

2. Sun, W., Duan, J., Liu, M., Hu, F., Jiang, X., Kong, Y.   2026. Experimental and geochemical evidence for magmatic origin of Li-Rb-Cs   in geothermal waters of the Yangbajing-Gulu Rift, Tibet. Geothermics, 136,   103614.

3. Jiang, H., Chu, X., Wang, J. M., Ji, W. Q., Cao, W., Hu, F.,   Liu, X. C., Wu, F. Y. 2026. Discovery of a late Eocene–Early Oligocene ultra-high temperature (UHT) migmatite in the   Gangdese batholith at Nyingchi, southern Tibet and its tectonic implications.   Lithos, 108399.

4. Huang, K., Yu, M., Guo, C., Ma, X., Niu, J., Zhao, J., Hu, F.,   Liu, X. 2026. The indicative significance of apatite in the Ganfang region   for lithium mineralization. Ore Geology Reviews, 188, 107105.

5. Chen, G., Zha, K., Li, H., Cheng, L., Jia, Y., Huang, R., Zavala,   C., Xie, Y. C., Hu, F. 2026. Evolution of Cretaceous sediment   provenance in the Danxia Basin, southeast China: Implications for tectonic   and landscape reorganization in Cathaysia. Tectonics, 45(1), e2025TC009218.

6. Ding, Z. Y., Liu, S. K., Su, B. X., Li, W. J., Hu, F. Y.,   Sakyi, P. A. 2025. Lithium isotope fractionation during granitic magma   differentiation: insights from whole rock and mineral analyses. Journal of   Petrology, 66(6), egaf048.

7. 吴福元, 刘小驰, 王佳敏, 陈厚彬, 胡方泱, 刘志超.   2025. 高分异花岗岩与高纯石英. 岩石学报,   41(10), 3243-3277.

8. 邢璐遥, 刘小驰, 李雪震, 赵向英, 胡方泱, 杨浩, 吴福元. 2025. 翁波穹隆锂辉石伟晶岩的发现及对喜马拉雅西段锂成矿作用的指示意义. 岩石学报, 41(9), 2982-2999.

9. 赵向英, 刘小驰, 邢璐遥, 李雪震, 赵俊兴, 胡方泱,   吴福元. 2025. 喜马拉雅造山带亚东地区锂辉石伟晶岩的识别及其地质特征分析. 岩石学报, 41(9), 3000-3018.

10. 李雪震, 刘小驰, 邢璐遥, 赵向英, 蒲浩澜, 胡方泱,   吴福元. 2025. 喜马拉雅造山带木斯塘锂辉石伟晶岩的发现及其指示意义. 岩石学报, 41(7), 2243-2259.

11. 次仁顿珠, 刘小驰, 毛国正, 刘成林, 吴魏, 赵向英, 邢璐遥, 胡方泱, 赵俊兴,   李俊瑜, 多吉, 吴福元. 2025. 西藏康马锂辉石伟晶岩的发现与特提斯喜马拉雅锂资源前景. 岩石学报, 41(4), 1121-1134.

12. 李家亮, 纪伟强, 胡方泱,   徐强. 2025. 青藏高原拉萨地体中新世岩浆演化与稀有金属成矿作用. 岩石学报, 41(3), 859-883.

13. Sun, G., Liu, S., Li, S., Kusky, T. M., Hu, F., Bao, H.,   Gao, L., Hu, Y. L., Yu, S. Y., Dai, L. M., Wang, L. T., Wang, X. 2025.   Neoarchean orogenic belt evolution in the northeast North China Craton:   Implications for the reconstruction of early Earth’s microplates. Precambrian Research, 417, 107659.

14. Wu, F. Y., Liu, X. C., Hu, F. Y., Xie, L., Wang, R. C.   2024. Himalayan leucogranites: rare-metal resources. Elements, 20(6),   401-408.

15. 侯康师, 王佳敏, 胡方泱,   杨雷. 2024. 希夏邦马峰地区矽卡岩型稀有金属矿化:岩石学特征、成矿时代及其地质意义. 岩石学报 40(05), 1527-1547.

16. 刘小驰, 杨雷, 何少雄, 胡方泱, 王佳敏. 2024. 希夏邦马峰淡色花岗岩岩石成因初步研究. 岩石学报, 40(05), 1446-1460.

17. 褚杨, 郭宜琳, 刘谭杰, 刘小驰, 胡方泱, 雷宜阳,   林伟. 2024. 藏南拆离系活动与淡色花岗岩就位——以希夏邦马峰地区为例. 岩石学报 40(05), 1461-1474.

18. Cong, F., Wu, F. Y., Li, W. C., Sun, Z. B., Liu, X. C., He, D. F.,   Ji, W. Q., Hu, F. Y., Zhang, S. H., Huang, X. M. 2024. Crystal mush   rejuvenation in the formation of Triassic dacites in Mengku, SE Tibetan   Plateau. Journal of Asian Earth Sciences, 265, 106085.

19. Yang, L., Wang, J. M., Liu, X. C., Hu, F. Y., Hou, K. S.,   Fu, J. G., Li, G. M., Tian, Y. L., Wu, F. Y. 2024. Petrogenetic link between   leucogranite and spodumene pegmatite in Lhozhag, eastern Himalaya:   Constraints from U–(Th)–Pb geochronology and Li–Nd–Hf isotopes. Lithos, 470, 107530.

20. He, S. X., Spencer, C. J., Liu, X. C., Hu, F., Wang, J. M.,   Ji, W. Q., Wu, F. Y. 2024. Identification of Indian crustal melting beneath   Gangdese arc during India-Asia collision. Lithos, 470, 107549.

21. Wang, W., Liu, S., Cawood, P. A., Yao, J., Gao, L., Guo, R., Hu,   F., Lu, D., He, X. 2024. Early Neoarchean alternation of plate subduction   and deep mantle upwelling. Precambrian Research, 402, 107303.

22. Yao, J., Wang, W., Gao, L., Hu, F., Lu, D., He, X., Guo, L.   2024. Initiation of Mesoarchean nascent subduction zone in the North China   Craton. Bulletin, 136(3-4), 949-963.

23. Wang, J. M., Hou, K. S., Yang, L., Liu, X. C., Wang, R. C., Li, G.   M., Fu, J. G., Hu, F.-Y., Tian, Y. L., Wu, F. Y. 2023. Mineralogy,   petrology and PT conditions of the spodumene pegmatites and surrounding   meta-sediments in Lhozhag, eastern Himalaya. Lithos 456, 107295.

24. Huang, C., Wang, H., Shi, W., Sun, J., Hu, F., Xu, L.,   Yang, Y. H., Wu, S. T., Xie, L. W., Yang, J. 2023. In situ Rb-Sr dating of   mica by LA-ICP-MS/MS. Science China Earth Sciences 66, 2603-2621.

25. Yao, J., Wang, W., Gao, L., Hu, F., Lu, D., He, X., Guo, L.   2023. Initiation of Mesoarchean nascent subduction zone in the North China   Craton. Geological Society of America Bulletin.

26. Ding, Z. Y., Liu, S. K., Su, B. X., Li, W. J., Bai, Y., Pan, Q.   Q., Hu, F., Pang, K. N. 2023. Potassium isotope fractionation during   granite differentiation and implications for crustal K isotope heterogeneity.   Lithos 448, 107176.

27. 吴福元, 郭春丽, 胡方泱,   刘小驰, 赵俊兴, 李晓峰, 秦克章. 2023. 南岭高分异花岗岩成岩与成矿. 岩石学报 39(01), 1-36.

28. Gao, L., Liu, S., Cawood, P. A., Hu, F., Wang, J., Sun, G.,   Hu, Y. 2022. Oxidation of Archean upper mantle caused by crustal recycling.   Nature Communications 13(1), 3283.

29. Wang, Y., Zhu, D., Lin, C., Hu, F., Liu, J. 2022.   Quantifying the growth of continental crust through crustal thickness and   zircon Hf-O isotopic signatures: A case study from the southern Central Asian   Orogenic Belt. GSA Bulletin 134(7-8), 2072-2084.

30. 刘小驰, 吴福元, 王汝成, 刘志超, 王佳敏, 刘晨, 胡方泱, 杨雷, 何少雄. 2021. 珠峰地区热曲锂辉石伟晶岩的发现及对喜马拉雅稀有金属成矿作用研究的启示. 岩石学报 37(11), 3295-3304.

31. 赵俊兴, 何畅通, 秦克章, 施睿哲, 刘小驰, 胡方泱, 余可龙, 孙政浩. 2021. 喜马拉雅琼嘉岗超大型伟晶岩锂矿的形成时代、源区特征及分异特征. 岩石学报 37(11), 3325-3347.

32. He, S. X., Liu, X. C., Yang, L., Wang, J. M., Hu, F. Y.,   Wu, F. Y. 2021. Multistage magmatism recorded in a single gneiss dome:   Insights from the Lhagoi Kangri leucogranites, Himalayan orogen. Lithos 398,   106222.

33. Sun, G., Liu, S., Cawood, P. A., Tang, M., van Hunen, J., Gao, L.,   Hu, Y., Hu, F. 2021. Thermal state and evolving geodynamic regimes of   the Meso-to Neoarchean North China Craton. Nature Communications 12(1), 3888.

34. Cong, F., Wu, F.-Y., Li, W.-C., Wang, J.-G., Hu, F.-Y., He,   D.-F., Ji, W.-Q., Lin, W., Sein, K., 2021. Petrogenesis of the Main Range and   Eastern Province granites in eastern Myanmar: New insights from zircon U–Pb ages and Sr–Nd isotopes. Lithos 382–383, 105895.

35. Cong, F., Li, W.-C., Wu, F.-Y., Huang, L., Huang, X.-M., Sun, J.,   Liu, X.-C., Hu, F.-Y., Hu, S.-X., Wu, G.-H., 2020. Mesozoic crustal   growth in Mainland Southeast Asia: Zircon U-Pb and Hf isotopic evidence from   the Late Cretaceous Luyingtang granitic pluton in the northernmost SE Asian   granite Province, SW China. Journal of Asian Earth Sciences 190, 104151.

36. Cong, F., Wu, F.-Y., Li, W.-C., Mou, C.-L., Huang, X.-M., Wang,   B.-D., Hu, F.-Y., Peng, Z.-M., 2020. Origin of the Triassic Lincang   granites in the southeastern Tibetan Plateau: Crystallization from crystal   mush. Lithos 360–361, 105452.

37. Hu, Y., Liu, S., Gao, L., Sun, G., Guo, R., Fu, J., Wang, M., Hu,   F., 2019. Diverse middle Neoarchean granitoids and the delamination of   thickened crust in the Western Shandong Terrane, North China Craton. Lithos   348–349, 105178.

38. Liu, S., Fu, J., Lu, Y.-J., Chen, X., Wang, M., Hu, F.,   Gao, L., Sun, G., Hu, Y., 2019. Precambrian Hongqiyingzi Complex at the   northern margin of the North China Craton: Its zircon U-Pb-Hf systematics,   geochemistry and constraints on crustal evolution. Precambrian Research 326,   58–83.

39. Sun, G., Liu, S., Gao, L., Hu, Y., Guo, R., Fu, J., Wang, M., Ma,   C., Hu, F., 2019. Neoarchean sanukitoids and associated rocks from the   Tengzhou-Pingyi intrusive complex, North China Craton: Insights into   petrogenesis and crust-mantle interactions. Gondwana Research 68, 50–68.

40. Gao, L., Liu, S., Sun, G., Hu, Y., Guo, R., Fu, J., Wang, M., Hu,   F., 2019. Neoarchean crust-mantle interactions in the Yishui Terrane,   south-eastern margin of the North China Craton: Constraints from geochemistry   and zircon U-Pb-Hf isotopes of metavolcanic rocks and high-K granitoids.   Gondwana Research 65, 97–124.

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