太古宙铬铁矿成因

大陆俯冲过程中Cr的迁移与富集

沉积物重金属评价

2025.08-2030.07 ***铬铁矿找矿标志研究 深地重大专项青年课题 主持

2025.01-2026.12 南海北部锆钛砂矿的源-运-汇机制研究 自然资源部海底矿产资源重点实验室开放基金 主持

2024.01-2028.12 地幔物质循环与Cr-PGE-Ni聚集规律 国家重点研发计划 专题负责

2024.06-2025.12 新喀多尼亚Tiebaghi铬铁矿成因研究 重点实验室开放课题 主持

2024.01-2025.12 大陆深俯冲富Cr流体的性质与来源 国自科（青年） 主持

2024.01-2028.12 微粒金刚石与俯冲物质深部循环 国自科（重点）  参与

2022.07-2023.07 江苏省卓越博士后计划 江苏省人力资源和社会保障厅 主持

2023.01-2023.12 太古宙铬铁矿成因研究 中央高校基本业务费 主持

2023.01-2026.12 马达加斯加Andriamena铬铁矿成因研究 国自科（面上） 参与

2023.01-2023.12 铂族元素在豆荚状铬铁矿中的赋存状态 中央高校基金 参与

2022.01-2023.12 新喀里多尼亚Tiébaghi豆荚状铬铁矿成因研究 重点实验室开放课题 参与

2021.01-2022.12 大陆深俯冲过程中富HFSE(熔)流体性质和来源探究  重点实验室开放课题  参与

第一/通讯作者

(23)  Cai, P.J., Majka, J., Lian, D.Y.*, Yang, J.S.*, Wang, L., Ma, H.T., Rui, H.C., Bo, R.Z., Masoud, A.E., 2025. Large-scale impregnation of oceanic and continental slab-derived adakitic melts into the mantle wedge. Communications Earth & Environment, 6, 557.

(22) Ma, H.T., Cai, P.J.*, Lian, D.Y.*, Yang, J.S., 2025. Grenvillian S-type granites in the North Qaidam orogenic belt, NW China: Implications for the geodynamic evolution of the Rodinia supercontinent. Precambrian Research, 427, 107867. 

(21)  Liu, R., Cai, P.J.*, Chen, X.*, 2025. Knowledge Structure and Frontier Evolution of Research on Nickel Deposits. Minerals, 15, 5, 464.

(20)  Yuan, Q.Y., Rui, H.C., Bo, R.Z., Lian, D.Y.*, Cai, P.J.*, Wu, Y., Parlak, O., Dou, H.R., Ma, H.T., Masoud, A.E., 2025. Petrology, mineralogy, and geochemistry of major podiform chromite deposits in China: Implications for their genesis. Ore Geology Reviews, 179, 106508.

(19) Cai, P.J., Lian, D.Y.*, Aitchison, J.C., Cluzel, D., Zhou, R.J., Rui, H.C., Bo, R.Z., Ma, H.T., Yang, J.S., Masoud, A.E., 2025. Geochemical constraints on subduction-related mantle metasomatism of the Tiébaghi ophiolitic lherzolite in New Caledonia. Lithos, 496-497, 107948.

(18) Cai, P.J., Ma, X.H.*, 2024. Metallogenic regularity and main research progress of cobalt and nickel deposits in China. Journal of Geochemical Exploration, 266, 107574.

(17) Wang, J.W., Cai, P.J.*,Yang, J.S.*, Szilas, K., Lian, D.Y., Luo, Z.H., Xiong, F.H., 2024. Age and petrogenesis of Archaean chromitite from the Seqi Ultramafic Complex, southern West Greenland. Lithos, 482-483, 107714.

(16) Chai, L.F., Wei, L.,Cai, P.J. *,Kang, J., Zhang, Z., 2024. Risk assessment of land subsidence based on GIS in the Yongqiao area, Suzhou City, China.Scientific Reports,14,1,11377.

(15) Cai, P.J.*, Cai, G.Q.*, Yang, J.S., Li, X.J., Lin, J., Li, S., Zhao, L., 2023. Distribution, risk assessment, and quantitative source apportionment of heavy metals in surface sediments from the shelf of the northern South China Sea. Marine Pollution Bulletin, 187, 114589 

(14) Cai, P.J.*,Yang, J.S., Lian, D.Y.*, Wu, W.W., Yang, Y., Rui, H.C., 2022. Knowledge Structure and Frontier Evolution of Research on Chromitite: A Scientometric Review. Minerals, 12, 10, 1211. 

(13) Zhou, J., Cai, P.J.*, Yang ,C.P., Liu, S.F., Luo, W.D., Nie, X., 2022. Geochemical characteristics and genesis of ferromanganese nodules and crusts from the Central Rift Seamounts Group of the West Philippine Sea. Ore Geology Reviews, 145, 104923.

(12) Li, Y., Xu, Z.Q., Ren, H.H., Wang, D., Wang, J., Wu,Z., Cai, P.J.*,2022. Spatial distribution and source apportionment of heavy metals in topsoil of Weifang City, East China. Frontiers in Environmental Science, 10, 893938

(11) CaiP.J., Cai, G.Q.*, Li, X.J., Chen, X., Lin, J., Li, S., Zhao, L., 2022. Distribution and source determination of rare earth elements in sediment collected from the continental shelf off Hainan Island, China. Environmental Science and Pollution Research, 29, 3062–3071.

(10) Cai, P.J., Cai, G.Q.*, Chen, X., Li, S., Zhao, L., 2022.The concentration distribution and biohazard assessment of heavy metal elements in surface sediments from the continental shelf of Hainan Island. Marine Pollution Bulletin, 166, 112254.

(9) Cai, P.J.,Chen, X.*, Majka, J., Klonowska, I., Jeanneret, P., Xu, R.K., Zheng, Y.Y. , 2021. Two episodes of crust-mantle interaction in the chromitite-bearing Luofengpo mafic-ultramafic complex produced by oceanic subduction to continental collision during the North Qaidam orogeny. Gondwana Research,89, 247-264

(8) Cai, P.J., Xu, R.K., Zheng, Y.Y., Yin, Y.M., Chen, X., Fan, X.B., Ma, C., 2019. Fluid Inclusion and H–O–S–Pb Isotope Geochemistry of the YukaOrogenic Gold Deposit, Northern Qaidam, China. Geofluids, DOI: 10.1155/2019/6912519.

(7) 刘嘉,蔡鹏捷*,曾小华,曾小华，杜文洋，刘雷. 2021. 柴达木盆地北缘造山型金矿地质、成矿流体及成矿时代特征. 中国地质, 2021, 48 (02): 374-387.

(6) 蔡鹏捷,郑有业,鲁立辉,陈鑫,殷悦铭,侯维东,韩登辉,许荣科,2019. 柴北缘滩间山金矿黄铁矿微量元素特征:指示多阶段金矿化事件. 中国有色金属学报, 29(10):2381-2393.

(5) 蔡鹏捷, 郑有业, 陈鑫, 白杰, 许荣科, 2019. 柴达木盆地北缘开屏沟纯橄岩中铬铁矿环带成因及其构造意义. 地质学报, 93(03): 647-660.

(4) 蔡鹏捷,张宇, 许荣科, 郑有业, 国显正, 陈鑫, 2019. 柴北缘双口山石英正长岩锆石U-Pb定年、地球化学及Sr-Nd同位素特征.大地构造与成矿学, 43(02): 322-338.

(3) 蔡鹏捷,许荣科, 郑有业, 陈鑫, 刘嘉, 俞军真, 2018. 柴北缘从大洋俯冲到陆陆碰撞:来自开屏沟造山带M型橄榄岩的证据. 地球科学, 43(08): 2875-2892.

(2) 蔡鹏捷,国显正,郑有业,孙述海,刘嘉,陈鑫,俞军真,许荣科, 2018. 岩浆型Ni-Cu-(PGE)硫化物矿床研究现状及进展.地质论评,64(4):956-979.

(1) 蔡鹏捷,许荣科,朱本杰,陶长才,廖明迅,刘嘉,王红军,卢锐,杜文洋, 2016.湖北嘉鱼蛇屋山红土型金矿研究回顾与展望.地质论评,62(02):389-397.

科普文章

(2) 蔡鹏捷,连东洋 ,芮会超 ,陈鑫, 2024. 铬：从地球深处到现代工业的奇妙旅程 . 自然资源科普与文化, 04, 4-9.

(1) 蔡鹏捷. 2021. 有孔虫：海洋的记录者. 自然资源科普与文化, 01, 20-23.

       合作文章

(22) Ma, H.T., Cai, P.J., Rui, H.C., Bo, R.Z., Parlak, O., Lian, D.Y., Yang, J.S., 2026. Melt percolation and channelized melt flow in Neo-Tethyan oceanic lithospheric mantle. Lithos, 532-533, 108533.

(21) Ma, H.T., Yang, J.S., Cai, P.J., 2026. Factors controlling the formation of high-Cr podiform chromite deposits. Journal of Asian Earth Sciences, 299, 106958.

(20) Rui, H.C., Doucet, L.S., Lissenberg, C.J., Lian, D.Y., Li, J., Cai, P.J., Lai, S.M., Zhu, J.X., He, H.P., Yang, J.S., 2026.  Melt flow control on lithological and geochemical heterogeneity of the oceanic upper mantle, National Science Review, 2026, https://doi.org/10.1093/nsr/nwag130.

(19) Hui-Chao Rui; Olivier Namur; Dong-Yang Lian*; Peng-Jie Cai; Jie Li; Yurisley Valdes-Mariño; Jing-Sui Yang; Hong-Ping He; Modification of oceanic lithospheric mantle by percolated melts sourced from recycled ancient crust: Evidence from Ca-Os isotopes of refractory harzburgites, Chemical Geology, 2025, 123077.

(18) Bo, R.Z., Dilek, Y., Li, W.Q., Nasir, S., Cai, P.J., Rui, H.C., Du, D.H., An, S.C., Lu, Y.X., Duan, H.C., Lian, D.Y., Yang, J.S., Masoud, A.E., 2025. Iron isotopic fractionation during seafloor hydrothermal alteration of oceanic upper crust, as recorded in Geotimes lavas of Semail ophiolite, Oman, Chemical Geology, 681, 122717.

(17) Bo, R.Z.,Cai, P.J., Lian, D.Y.,Yang, J.S.,Nasir, S., Rui, H.C.,Lu, Y.X., Cao, C.Q., Masoud, A.E., 2025. Masoud; Transitional chromitites within the Maqsad crust-mantle transition zone of the Semail ophiolite formed above the nascent forearc setting, Lithos, 502-503: 10802.

(16) Ma, H.T., Dilek, Y., Lian, D.Y., Cai, P.J., Jaynaada, M., Aadhiseshan, K.R., Yang, J.S., 2025. Parental magma and mantle source compositions of chromitites in the Mesoarchean Nuggihalli greenstone belt, India: Evidence for Archaean subduction zone magmatism. Journal of the Geological Society, 182,2, jgs2024-158.https://doi.org/10.1144/jgs2024-158

(15) Chen, X., Schertl, H.P., Khan, J., Cai, P.J., Lian, D.Y., Wang, J.S., Yu, C.T., Lin, H., Jiang, X.J., 2025. Scandium mineralization during ultramafic-mafic magmatism in the subduction zone. Chemical Geology, 673, 122556. https://doi.org/10.1016/j.chemgeo.2024.122556

(14) Jiang, X.J., Chen, X., Hoare, L., Schertl, H.P., Palmer, M.R., Zhang, W., Cai, P.J., Liu, H., Zheng, Y.Y., Gao, S.B., 2024. Substantial in situ Ti isotope variations in rutile record source and fluid evolution of porphyry copper mineralization systems. GSA Bulletin, https://doi.org/10.1130/B37798.1

(13) Jiang, X.J., Chen, X., Jiang, S.Y., Hoare, L., Zhang, W., Lina, D.Y., Cai, P.J., Xu, Y.M., Liu, H., 2024. Immiscibility of carbonatitic and alkaline silicate melts from an evolved ultramafic magma: Titanite geochronology and in-situ Tisingle bondNd isotope insights. Chemical Geology, 670, 122433. https://doi.org/10.1016/j.chemgeo.2024.122433

(12) Lian, D.Y., Liu, F., Cai, P.J., Majka, J., Xu, Z.Q., Yang, J.S., 2024. Osmium and zinc isotope constraints on the origin of chromitites from the Yarlung-Zangbo ophiolites, Tibet, China. Mineralium Deposita, 59, 1089-1107. https://doi.org/10.1007/s00126-024-01252-9

(11) Wu, W.W., Yang, J.S., Dilek, Y., Das, S., Lian, D.Y., Cai, P.J., Wang, Y., Yang, Y., Wen, Y.Y., 2024. Two-pyroxene, intergrowth exsolution textures in ophiolitic chromites: implications for the deep mantle origin of the Mirdita Ophiolite, Albania. Journal of the Geological Society, 181,1, jgs2023-128. https://doi.org/10.1144/jgs2023-128

(10) Bo, R.Z., Dilek, Y., Nasir, S., Wu, W.W., Cai, P.J., Lu, Y.X., Lian, D.Y., Yang, J.S., 2023. Mineral and whole-rock geochemistry of high-Al podiform chromitites in the Fizh Massif of the Cretaceous Oman ophiolite: origin of hydrous N-MORB melts in a nascent forearc setting. Journal of the Geological Society, 180,6, jgs2023-047. https://doi.org/10.1144/jgs2023-047

(9) Yang, Y., Yang, J.S., Wu, W.W., Cai, P.J., Ma, H.T., 2023. Microstructural Insights into the Evolution of Ophiolitic Chromite from Luobusha. Minerals, 13, 8, 1047. https://doi.org/10.3390/min13081047

(8) Chen, X., Schertl, H.P., Gu, P.Y., Zheng, Y.Y., Xu, R.K., Zhang, J.Y., Cai, P.J., Lin, C.G., 2021. Newly discovered MORB-Type HP garnet amphibolites from the Indus-Yarlung Tsangpo suture zone: Implications for the Cenozoic India-Asia collision. Gondwana Research, 90, 102-117. https://doi.org/10.1016/j.gr.2020.11.006

(7) Chen, X., Zheng, Y.Y., Gao, SB., Wu, S., Jiang, X.J., Jiang, J.S., Cai, P.J., Lin, C.G., 2020.Ages and petrogenesis of the late Triassic andesitic rocks at the Luerma porphyry Cu deposit, western Gangdese, and implications for regional metallogeny. Gondwana Research, 85, 103-123. https://doi.org/10.1016/j.gr.2020.04.006

(6) Chen, X., Zheng, Y.Y., Xu, R.K., Gu, P.Y., Yu, J.Y., Bai, J., Cai, P.J., Jiang, X.J., 2020. Subduction channel fluid-rock interaction: Indications from rutile-quartz veins within eclogite from the Yuka terrane, North Qaidam orogen. Geoscience Frontiers, 11, 2, 635-650. https://doi.org/10.1016/j.gsf.2019.07.009

(5) Chen, X., Schertl, H.P., Cambeses, A., Gu, P.Y., Xu, R.K., Zheng, Y.Y., Jiang, X.J., Cai, P.J., 2019. From magmatic generation to UHP metamorphic overprint and subsequent exhumation: A rapid cycle of plate movement recorded by the supra-subduction zone ophiolite from the North Qaidam orogen. 350-351, 105238. https://doi.org/10.1016/j.lithos.2019.105238

(4) Chen, X., Xu, R.K., Zheng, Y.Y., Gao, S.B., Cai, P.J., Yu, J.Z., Wang, Q.M., 2019.The geodynamic setting of Dulan eclogite-type rutile deposits in the North Qaidam orogen, western China. Ore Geology Reviews, 110, 102936. https://doi.org/10.1016/j.oregeorev.2019.102936

(3) Gao, S.B., Chen, X., Xu, R.K., Cai, P.J., Lu, L.H., Hou, W.D., Guo, X.Z., 2019. Tracking the timing and nature of protolith, metamorphism, and partial melting of tourmaline-bearing migmatites by zircon U-Pb and Hf isotopic compositions in the Yuka terrane, North Qaidam UHP metamorphic belt. Geological Journal, 54, 2, 1013-1036. https://doi.org/10.1002/gj.3362

(2) Chen, X., Xu, R.K., Zhneg, Y.Y., Cai, P.J., 2018. Petrology and geochemistry of high niobium eclogite in the North Qaidam orogen, Western China: Implications for an eclogite facies metamorphosed island arc slice. Journal of Asian Earth Sciences, 164, 38-397.https://doi.org/10.1016/j.jseaes.2018.07.003

(1) Chen, X., Zhneg, Y.Y., Xu, R.K., Wang, H.M., Jiang, X.J., Yan, H.Z., Cai, P.J., Guo, X.Z., 2016. Application of classical statistics and multifractals to delineate Au mineralization-related geochemical anomalies from stream sediment data: a case study in Xinghai-Zeku, Qinghai, China. Geochemistry: Exploration, Environment, Analysis,16 (3-4): 253–264.https://doi.org/10.1144/geochem2016-424