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曾罡
  • 职称: 副教授 职称: 副教授
  • 岗位: 仅研究系列选择
  • 联系电话: 025-89680895
  • 办公地址: 朱共山楼536
  • 电子邮件: zgang@nju.edu.cn
  • 课题组链接: http://www.rockingmantle.com/

个人简介

教育经历

工作经历

学术兼职

研究方向

重点关注地幔物质组成、壳幔相互作用机制及幔源岩浆作用过程(如玄武岩成因、幔源岩浆的深部演化过程等)。近年来,以中国东部玄武岩及其蕴含的橄榄石斑晶、熔体包裹体等为主要研究对象,通过元素地球化学、Sr-Nd-Pb-Hf-Mg-Fe同位素和橄榄石矿物化学等联合示踪的方法,深入探讨了玄武岩的地幔源区岩性特征与深部过程。尤其关注在地球物质的深部循环过程中,碳、氟、氯等挥发分对物质循环、元素配分、金属迁移-富集等过程的潜在影响。


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研究生报考专业:矿物学、岩石学、矿床学(岩石学方向)


开授课程

本科大三专业必修课《岩浆岩与变质岩》、《地球物质循环:岩浆岩与变质岩岩石学》

本科大二专业必修课《岩石学》、《地球物质循环:岩石学基础》

全校公选课《火山的前世今生》


科研项目

20242026   国家自然科学基金优秀青年基金(主持) “地幔中氟-氯的熔体包裹体示踪”

20222027   国家重点研发计划项目(骨干)   “东亚陆缘古太平洋板块俯冲的构造-岩浆活动及浅部效应”

2022–2026   国家自然科学基金重点基金(骨干) “从大陆火山岩视角了解深部地幔化学储库的属性”

2017–2020   国家自然科学基金面上基金(主持) “中国东南部新生代小规模溢流玄武岩成因研究”

2015–2019   国家自然科学基金重点基金(骨干) “华夏地块古生代-早中生代花岗岩及相关岩石成因与陆壳再造”

2014–2017   国家自然科学基金面上基金(骨干) “南太平洋Louisville海山玄武岩的成因与源区特征”

2013–2015   国家自然科学基金青年基金(主持) “中国东部新生代玄武岩的成因 — 以苏皖地区玄武岩典型剖析”

学术成果

学术任职情况


  • 中国地质学会岩石专业委员会委员 

  • 中国矿物岩石地球化学学会岩浆岩专业委员会委员

  • 中国矿物岩石地球化学学会火山及地球内部化学专业委员会委员 

  • 中国灾害防御协会火山专业委员会委员

  • 《华东地质》编委会委员


学术奖励情况


  • 2023:19届侯德封矿物岩石地球化学青年科学家奖

  • 2016:江苏省科学技术奖一等奖(排名第3;项目名称:中国东南部地幔性状及壳幔相互作用研究)

  • 2022-2026:江苏省“333高层次人才培养工程”第三层次



主要科研成果



53. Zeng, G.*, Wang, X.-J., Zhang, X.-Y., Zhong, Y., Shi, J.-H., Yu, X., Xie, L.-W., Chen, L.-H., 2025. Kinetic Mg Fe isotope fractionation in natural basalts during melt-peridotite interaction. Chem. Geol. 672, 122514.

52. Yu, H.-Y., Zhang, H.-L., Zhang X.-Y., Jiang J.-X., Liang, Y.-K., Chen, L.-H., Zeng, G.*, 2025. Characteristics and potential origin of carbonate components in the Louisville seamounts. J. Earth Sci., accepted.

51. 张叶凡, 陈立辉, 王小均, 刘建强, 曾罡, 周中彪. 2024. 松花江新生代斜斑玄武岩中斜长石巨斑晶的成因及其对长白山天池造盾期岩浆储运系统的制约. 岩石学报, 40(7): 2019-2036.

50. Zhang, H.-L., Zeng, G.*, Chen, L.-H., Liu, J.-Q., Yu, J.-H., Xu, X.-S., 2024. Evaluation of CO2 concentration in a carbonated eclogite mantle source: A new attempt based on the compositions of olivine phenocrysts. Lithos, 107669. 

49. Dai, C.-C., Wang, X.-J.*, Chen, L.-H., Hanyu, T., Zhang, X.-Y., Zeng, G., Xie, L.-W., 2024. Iron isotopic compositions of HIMU Ocean island basalts: Implications for the mantle source lithology. Lithos 470-471, 107531. 

48. Wang, X.-J.*, Chen, L.-H., Hanyu, T., Zhou, Z.-B., Liu, J.-Q., Zeng, G., Zou, Z.-Q., Bai, J.-H., 2024. Calcium isotopic variability in hotspot lavas controlled by partial melting and source lithological heterogeneity. Chem. Geol. 644, 121857. 

47. 曾罡*, 张慧丽, 刘建强, 陈立辉. 2023. 海南岛玄武岩橄榄石斑晶中熔体包裹体示踪氟、氯深部循环. 矿物岩石地球化学通报, 42, 20232.

46. Zhang, H.-L., Zeng, G.*, Liu, J.-Q., Chen, L.-H., Yu, J.-H., Wu, B., Wang, X.-J., Xu, X.-S., Liu, X.-W., 2023. Carbonated eclogitic component beneath eastern China revealed by olivine phenocrysts in nephelinites. Chem. Geol. 640, 121744.

45. 郑志翀曾罡*张慧丽刘建强陈立辉周中彪. 2023. 中国东北鸡西新生代玄武岩源区岩性制约. 高校地质学报, 29: 186-200.

44. 熊巧曾罡郑志翀张慧丽周中彪王小均刘建强陈立辉*. 2023. 东北牡丹江地区古近纪高镁安山岩的发现及其岩石学特征. 高校地质学报, 29: 161-173.

43. Shi, J. H., Zeng G.*, L. H. Chen, X. J. Wang, J. Q. Liu, L. W. Xie, Y. H. Yang, and H. L. Zhang. 2023. Lithology of EM1 Reservoir Revealed by Fe Isotopes of Continental Potassic Basalts. J. Geophys. Res.: Solid Earth, 128(1). https://doi.org/10.1029/2022jb025133.

42. Shen, J.*, Zuo, Z., He, Y., Li, S., Huang, J., Zeng, G., Qin, L.,2023. Chromium isotope system of intraplate basaltic lavas: Implication for recycling materials into mantle. Lithos 454-455, 107264. 

41. Wen, D.-J., Hu, X.*, Chapman, T., Zeng, G., Ma, A.-L., Wang, R.-Q., 2023. Late Cretaceous bimodal volcanic rocks in Shuanghu induced by lithospheric delamination beneath the Southern Qiangtang, Tibet. Lithos 460-461, 107368.

40. 陈立辉, 曾罡, 刘建强, 王小均, 张超. 2022. 从大陆火山岩视角了解深部地幔化学储库的属性. 岩石学报, 38(12): 3703-3711. doi: 10.18654/1000-0569/2022.12.10.

39. Liu, J.Q.*, Chen, L.H., Wang, X.J., Zhang, H.L., Zeng, G., Saskia, E., Zhang, L., Ren, Z.Y. 2022. Olivine and melt inclusion chemical constraints on the nature and origin of the common mantle component beneath eastern Asia.Contributions to Mineralogy and Petrology, 177. https://doi.org/10.1007/s00410-022-01981-y.

38. Sheng S. Z., Wang S. J., Yang X. M., Chen L. H., Zeng G., Xiao Y., Shen J., Dong X. H & Lv Y. W. (2022) Sulfide dissolution on the nickel isotopic composition of basaltic rocks. Journal of Geophysical Research: Solid Earthhttps://doi.org/10.1029/2022JB024555.

37. Liu, J.-Q.*, Chen, L.-H., Wang, X.-J., Zhang,X.-Y., Zeng, G., Saskia, E., Murphy, D.-T., Collerson, K.-D., Komiya,T., Krmicek, L.(2022) Magnesium and zinc isotopic evidence for the involvement of recycled carbonates in thepetrogenesis of Gaussberg lamproites,Antarctica. Chemical Geology. https://doi.org/10.1016/j.chemgeo.2022.121067.

36. Zhang, H.-L., Zeng, G.*, Zhang, C., Zhang, W.-L., Chen, L.-H., Yu, J.-H., 2022. Electron Probe Microanalysis measurement of F-Cl-Nb-P for Geological Glasses. Geostandards and Geoanalytical Research, 46, 851-864. https://doi.org/10.1111/ggr.12454.

35. Zhang, X.Y., Chen, L.H., Wang, X.J., Hanyu, T., Hofmann, A.W., Komiya, T., Nakamura, K., Kato, Y., Zeng, G., Gou, W.X., Li, W.Q., 2022. Zinc isotopic evidence for recycled carbonate in the deep mantle. Nature Communications, 13, 6085.

34Shi, J.-H., Zeng, G.*, Chen, L.-H., Hanyu, T., Wang, X.-J., Zhong, Y., Xie, L.-W., Xie, W.-L., 2022. An eclogitic component in the Pitcairn mantle plume: evidence from olivine compositions and Fe isotopes of basalts. Geochimica et Cosmochimica Acta, 318, 415-427.  https://doi.org/10.1016/j.gca.2021.12.017. 

33. Zeng, G.*,  Chen, L.-H.*, Hofmann, A.W.*, Wang, X.-J., Liu, J.-Q., Yu, X., Xie, L.-W., 2021. Nephelinites in eastern China originating from the mantle transition zone. Chem. Geol., https://doi.org/10.1016/j.chemgeo.2021.120276. 

32. Liu J. Q.*Erdmann, S.Chen L. H., Zhang H.L., Wu B., Zeng G.Wang X. J., Lei Z. L., Yu X. (2021). Petrological evidence for magma recharge and mixing beneath the Ma'anshan monogenetic volcano of Xiaogulihe in Northeast ChinaLithos382-383, https://doi.org/10.1016/j.lithos.2020.105928.

31. Wang X. J., Chen L. H., Hanyu T., Zhong Y., Shi J. H., Liu X. W., Kawabata H., Zeng G., Xie L. W.(2021)Magnesium isotopic fractionation during basalt differentiation as recorded by evolved magmas. Earth and Planetary Science Letters, 565, https://doi.org/10.1016/j.epsl.2021.116954. 

30. Jiang, D.-S., Xu, X.-S., Wang, X.-J., Zeng, G., Chen, A.-X., Huang, B., Huang, F., 2021. Geochemical evidence for the Paleo-Pacific plate subduction at ~125 Ma in Eastern China. Lithos 398-399.

29. Zhu-Liang LeiZeng, G.*, Jian-Qiang Liu*, Xiao-Jun Wang, Li-Hui Chen, Xiao-Yu Zhang, Jin-Hua Shi (2021), Melt-lithosphere interaction controlled compositional variations in mafic dikes from Fujian province, southeastern China. Journal of Earth Science, 32, 1445-1453, https://doi.org/10.1007/s12583-020-1358-y.

28. 何叶, 陈立辉, 曾罡, 王小均 (2020), 浙江建德新生代玄武岩源区特征及其成因, 高校地质学报, 26, 241-254.

27. 雷祝梁曾罡*王小均陈立辉 (2019), 中国东南部晚中生代基性岩脉地幔源区的岩性演化历史地球科学, 44, 1159-1168. 

26. Xun YuZeng, G.*, Li-Hui Chen, Xiao-Jun Wang, Jian-Qiang Liu, Lie-Wen Xie, Tao Yang (2019), Evidence for rutile-bearing eclogite in the mantle source of the Cenozoic Zhejiang basalts, eastern China, Lithos, 324-325, 152-164, doi: 10.1016/j.lithos.2018.11.003

25. Xun Yu, Zeng G.*, Li-Hui Chen, Sen-Lin Hu & Zhi-Qiang Yu (2019): Magma–magma interaction in the mantle recorded by megacrysts from Cenozoic basalts in eastern China, International Geology Review, 61, 675-691, doi: 10.1080/00206814.2018.1446190. 

24. Y. He, L.-H. Chen, J.-H. Shi, Zeng, G., X.-J. Wang, X.-Q. Xue, Y. Zhong, S. Erdmann & L.-W. Xie (2019). Light Mg isotopic composition in the mantle beyond the Big Mantle Wedge beneath eastern Asia. Journal of Geophysical Research: Solid Earth, 124, 8043-8056,  doi: 10.1029/2018jb016857.

23. 薛笑秋, 陈立辉, 刘建强, 何叶, 王小均, 曾罡, 钟源 (2019). 中国东北软流圈地幔中的原始橄榄岩质地幔:来自大兴安岭地区新生代玄武岩的地球化学证据. 地球科学, 44, 1143-1158.

22. Wang, Z.-Z., Liu, S.-A., Chen, L.-H., Li, S.-G.& Zeng, G.  (2018), Compositional transition in natural alkaline lavas through silica-undersaturated melt–lithosphere interaction. Geology, 46, 771-774, doi: 10.1130/g45145.1.

21. *, 郑丽波, 陈立辉, 刘建强, 张欢, 张甬江, 施金华 (2017), 南海洋脊抽吸作用对其周边新生代玄武质岩浆活动的影响, 高校地质学报, 23, 373-382.

20. Xu, W., X. Xu*, and Zeng G. (2017), Crustal contamination versus an enriched mantle source for intracontinental mafic rocks: Insights from early Paleozoic mafic rocks of the South China Block, Lithos, 286, 388-395, doi: 10.1016/j.lithos.2017.06.023.

19. Zeng G., L.-H. Chen*, X. Yu, J.-Q. Liu, X.-S. Xu, and S. Erdmann (2017), Magma-magma interaction in the mantle beneath eastern China, J. Geophys. Res.: Solid Earth, 122, doi: 10.1002/2017jb014023.

18. Yu, X., Chen L.-H.*, and Zeng G. (2017), Magmatic recharge buffers the isotopic compositions against crustal contamination in formation of continental flood basalts, Lithos, 284-285, 1-10, doi: 10.1016/j.lithos.2017.03.027.

17. Zhong, Y., L.-H. Chen*, X.-J. Wang, G.-L. Zhang, L.-W. Xie, and Zeng, G. (2017), Magnesium isotopic variation of oceanic island basalts generated by partial melting and crustal recycling, Earth Planet. Sci. Lett., 463, 127-135.

16. Liu, J.-Q., Chen L.-H.*, Wang X.-J., Zhong Y., Yu X., and Zeng G.(2017), The role of melt-rock interaction in the formation of Quaternary high-MgO potassic basalt from the Greater Khingan Range, Northeast China. J. Geophys. Res. Solid Earth, 122, doi: 10.1002/2016JB013605.

15. Chu, Z.*, Y. Yan, Zeng G., W. Tian, C. Li, Y. Yang, and J. Guo (2017), Petrogenesis of Cenozoic basalts in central-eastern China: Constraints from Re-Os and PGE geochemistry, Lithos, 278-281, 72-83.

14. 林蔚涵, 刘建强, 陈立辉*刘建强, 王小均, 钟源, 曾罡 (2017), 大兴安岭新生代高镁安山岩的确认. 高校地质学报, 23, 16-25.

13. Zeng G.*, Z.-Y. He, Z. Li, X.-S. Xu, and L.-H. Chen (2016), Geodynamics of paleo-Pacific plate subduction constrained by the source lithologies of Late Mesozoic basalts in southeastern China, Geophys. Res. Lett., 43, 10189-10197, doi:10.1002/2016GL070346.

12. Zeng G.*, Huang X.-W., Zhou M.-F., Chen L.-H., Xu X.-S. (2016), Using chalcophile elements to constrain crustal contamination and xenolith-magma interaction in Cenozoic basalts of eastern China, Lithos 258-259: 163-172.

11. Liu, J.-Q., Chen L.-H.*, Zeng G., Wang X.-J., Zhong Y., and Yu X. (2016), Lithospheric thickness controlled compositional variations in potassic basalts of Northeast China by melt-rock interactions, Geophys. Res. Lett., 43, doi:10.1002/2016GL068332.

10. Yu, X., L.-H. Chen*, and Zeng G.(2015), Growing magma chambers control the distribution of small-scale flood basalts, Scientific Reports, 5, doi: 10.1038/srep16824.

9. 冒福根, 陈立辉*, 杨怀仁, 刘建强, 曾罡 (2015), 五大连池钾质火山岩中辉石斑晶的反环带结构研究及其对岩浆演化的约束. 高校地质学报, 21, 507-522. ‍

8. Yu, X.*, C.-T. A. Lee, L.-H. Chen, and Zeng G. (2015), Magmatic recharge in continental flood basalts: Insights from the Chifeng igneous province in Inner Mongolia, Geochem. Geophys. Geosyst., 16, 2082-2096.

7. 陈霞玉, 陈立辉*, 陈旸, 曾罡, 刘建强 (2014), 中国中—东部地区新生代玄武岩的分布规律与面积汇总. 高校地质学报, 20, 507-519.

6. Zeng G.*, L.-H. Chen, S.-L. Hu, X.-S. Xu, and L.-F. Yang (2013), Genesis of Cenozoic low-Ca alkaline basalts in the Nanjing basaltic field, eastern China: The case for mantle xenolith-magma interaction, Geochem. Geophys. Geosyst., 14, 1660-1677, doi: 10.1002/ggge.20127.

5. 陈立辉*, 曾罡, 胡森林, 俞恂, 陈霞玉 (2012), 地壳再循环与大陆碱性玄武岩的成因:以山东新生代碱性玄武岩为例.  高校地质学报 18, 16-27.

4. Zeng G., L. H. Chen*, A. W. Hofmann, S. Y. Jiang, and X. S. Xu (2011), Crust recycling in the sources of two parallel volcanic chains in Shandong, North China, Earth Planet. Sci. Lett., 302, 359-368.

3. Zeng G., L. H. Chen*, X. S. Xu, S. Y. Jiang, and A. W. Hofmann (2010), Carbonated mantle sources for Cenozoic intra-plate alkaline basalts in Shandong, North China, Chem. Geol., 273, 35-45.

2. Chen, L. H.*, Zeng G., S. Y. Jiang, A. W. Hofmann, and X. S. Xu (2009), Sources of Anfengshan basalts: Subducted lower crust in the Sulu UHP belt, China, Earth Planet. Sci. Lett., 286, 426-435.

1. 罗丹, 陈立辉*, 曾罡 (2009), 陆内强碱性火山岩的成因:以山东无棣大山霞石岩为例. 岩石学报 25, 311-319.



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