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。主要学术成果包括：（1）通过对秦岭造山带早中生代花岗质岩石的研究，揭示了碰撞造山过程中多源区岩浆相互作用的过程；（2）将岩浆作用与区域变质作用和沉积历史等结合，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；（3）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，据此分别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。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。已发表论文20余篇，其中第一作者SCI论文7篇。

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

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

1. 2018年第九届李四光优秀博士研究生奖
2. 2018年北京大学优秀毕业生
3. 2017年博士研究生国家奖学金
4. 2017年北京大学创新奖（学术类）
5. 2016年博士研究生国家奖学金

1. 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
2. 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
3. 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
4. 国家自然科学基金基础科学中心项目（41888101），大陆演化与季风系统演变，2019.01-2028.12，参与
5. 国家自然科学基金面上项目（41972065），珠峰地区高喜马拉雅P-T-t-D轨迹重建及对碰撞造山机制的制约，2020.01-2023.12，参与

第一作者及通讯作者文章：
*通讯作者

1. 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.
2. 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.
3. 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.
4. 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.
5. 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.
6. 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.
7. 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. 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.
2. 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.
3. 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.
4. 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.
5. 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.
6. 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.
7. 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.
8. Fu, J., Liu, S., Cawood, P.A., Wang, M., Hu, F., Sun, G., Gao, L., Hu, Y., 2018. Neoarchean magmatic arc in the Western Liaoning Province, northern North China Craton: Geochemical and isotopic constraints from sanukitoids and associated granitoids. Lithos 322, 296–311.
9. Gao, L., Liu, S., Sun, G., Guo, R., Hu, Y., Fu, J., Wang, M., Ma, C., Hu, F., 2018. Petrogenesis of late Neoarchean high-K granitoids in the Western Shandong terrane, North China Craton, and their implications for crust-mantle interactions. Precambrian Research 315, 138–161.
10. Liu, S., Wang, M., Wan, Y., Guo, R., Wang, W., Wang, K., Guo, B., Fu, J., Hu, F., 2017. A reworked ～3.45Ga continental microblock of the North China Craton: Constraints from zircon U-Pb-Lu-Hf isotopic systematics of the Archean Beitai-Waitoushan migmatite-syenogranite complex. Precambrian Research, Archean to Proterozoic Evolution of the North China Craton 303, 332–354.
11. Fu, J., Liu, S., Wang, M., Chen, X., Guo, B., Hu, F., 2017. Late Neoarchean monzogranitic–syenogranitic gneisses in the Eastern Hebei–Western Liaoning Province, North China Craton: Petrogenesis and implications for tectonic setting. Precambrian Research, Archean to Proterozoic Evolution of the North China Craton 303, 392–413.
12. Deng, Z., Liu, S., Zhang, W., Hu, F., Li, Q., 2016. Petrogenesis of the Guangtoushan granitoid suite, central China: Implications for Early Mesozoic geodynamic evolution of the Qinling Orogenic Belt. Gondwana Research 30, 112–131.