汪在聰

2010/09-2014/02：德國柏林自由大學，地質系，博士，導師：Harry Becker

2007/09-2010/07：中國科學院地質與地球物理研究所，固體礦產資源研究室，碩士，導師：劉紅濤

2003/09-2007/07：中國地質大學（北京），地球科學學院，學士，導師：李勝榮

2016.09- ：中國地質大學（武漢），教授

2014/02-2016/09：柏林自由大學，博士後，導師：Harry Becker

2013/09-2014/02：柏林自由大學，研究助理

依託地質過程與礦產資源國家重點實驗室，建立準確分析親銅元素含量及非傳統穩定同位素的方法，利用其元素地球化學和宇宙化學性質，套用到地質樣品和隕石來研究：（1）地球及其它行星核幔分異、行星增生演化及增生物質成分；（2）地幔深部岩漿過程；（3）俯衝帶物質起源、遷移與循環；（4）金屬礦床成因。近期主要聚焦殼幔演化與相互作用及其資源效應，研究俯衝帶金屬和揮發性元素遷移演化以及膠東巨量金成礦的起源；建立和開發Ca、Fe、Cu、Zn、Zr等穩定同位素體系在殼幔演化相關領域的套用。

1.國家自然基金優秀青年基金：親鐵親銅元素地球化學（負責人，項目批准號41722302, 2017-2020，直接經費130萬）

2. 國家高層次人才項目（2016年）

3.面上基金：親銅元素在地幔熔體遷移交代過程中的地球化學行為及其意義（負責人，項目批准號41673027，2017-2020，直接經費72萬元）

4.《華北東部中生代岩漿作用與成礦深部過程》子課題：華北東部地幔源區親銅元素的分布及遷移過程（負責人，項目來源：深地資源勘查開採國家重點研發計畫，2016-2020,中央財政專項經費135萬元）

5.德國DFG自然科學基金BE1820/12-1 (2013-2015)：Siderophile volatile element depletion in Earth, Mars and in the aubrite parent body, 154,800€,項目骨幹（2/2）

1.建立了準確測定極低含量樣品中親鐵親銅元素含量的等離子質譜-同位素稀釋法，為研究太陽系早期演化、行星增生、核幔分異、幔源岩漿過程、殼幔相互作用和金屬礦床成因等領域科學問題提供了技術支撐。

2.系統研究了親銅元素在地幔岩漿過程中的地球化學行為，總結了地幔橄欖岩部分熔融、熔體交代富集、輝石岩脈和大洋地殼形成和演化等不同岩漿過程的內在聯繫；從Cu和Ag的地球化學角度揭示島弧分異過程中地殼深部硫化物堆晶是大陸生長的重要環節。

3.重新估計了S、Se、Te、Cu、Ag、Cd和In等親鐵親銅元素在矽酸鹽地球中的含量；認為S、Se、Te含量和比值與鉑族元素一致，均能反映地球地核形成之後增生物質的成分，並提出該物質可能帶來了地球上20-100%水的認識，有效的約束了地球上水的可能起源過程及其時間；提出地球主體增生物質的中度揮發性元素成分可能不能由隕石代表，更新了關於地球增生物質成分的經典模型。

4.新測得火星隕石中Cu、S、Se和Te含量，根據親銅元素之間的分異，系統闡明了火星隕石母岩漿具有硫化物不飽和的演化歷史，提出了火星內部並不富含硫的突破性認識，挑戰了過去三十年廣泛認為火星是富含硫的行星的傳統觀點，並提出火星的水可能在火星核形成前已經存在等認識。

5. 針對華北克拉通巨量爆發性金礦來源的難點問題，開發了高精度金分析方法，據此提出交代岩石圈地幔中金的強烈富集並不是成超大型金礦的前提，地幔源區並不異常富集金也能大成礦，其中揮發分起著關鍵作用的突破性認識。

6. 依託大型儀器Nu plasma 1700 MC-ICP-MS開發鈣同位素為代表的穩定同位素分析技術，套用於地幔橄欖岩和來自不同擴張速率下的洋殼樣品，系統理解了地幔岩漿和洋殼形成過程中的鈣同位素分餾。

1.Wang, Z., Cheng, H., Zong, K., Geng, X., Liu, Y., Yang, J., Wu, F., Becker, H., Foley, S. and Wang, C.Y. (2020) Metasomatized lithospheric mantle for Mesozoic giant gold deposits in the North China craton. Geology 48, 169-173.

2.Dai, W., Wang, Z., Liu, Y., Chen, C., Zong, K., Zhou, L., Zhang, G., Li, M., Moynier, F. and Hu, Z. (2020) Calcium isotope compositions of mantle pyroxenites. Geochim. Cosmochim. Acta 270, 144-159.

3.Wang, Z. (2019) Earth’s volatile-element jigsaw. Nat. Geosci. 12, 500-502.

4.Wang, Z., Park, J.-W., Wang, X., Zou, Z., Kim, J., Zhang, P. and Li, M. (2019) Evolution of copper isotopes in arc systems: Insights from lavas and molten sulfur in Niuatahi volcano, Tonga rear arc. Geochim. Cosmochim. Acta 250, 18-33.

5.Zou, Z., Wang, Z., Li, M., Becker, H., Geng, X., Hu, Z. and Lazarov, M. (2019) Copper Isotope Variations During Magmatic Migration in the Mantle: Insights From Mantle Pyroxenites in Balmuccia Peridotite Massif. Journal of Geophysical Research: Solid Earth 124, 11130-11149.

6.Chen, C., Ciazela, J., Li, W., Dai, W., Wang, Z., Foley, S.F., Li, M., Hu, Z. and Liu, Y. (2019a) Calcium isotopic compositions of oceanic crust at various spreading rates. Geochim. Cosmochim. Acta.

7.Chen, C., Dai, W., Wang, Z., Liu, Y., Li, M., Becker, H. and Foley, S.F. (2019b) Calcium isotope fractionation during magmatic processes in the upper mantle. Geochim. Cosmochim. Acta 249, 121-137.

8.Cheng, H., Wang, Z., Chen, K., Zong, K., Zou, Z., He, T., Hu, Z., Fischer-Gödde, M. and Liu, Y. (2019) High-precision Determination of Gold Mass Fractions in Geological Reference Materials by Internal Standardisation. Geostand. Geoanal. Res. 43, 663-680.

9.Li, M., Lei, Y., Feng, L., Wang, Z., Belshaw, N.S., Hu, Z., Liu, Y., Zhou, L., Chen, H. and Chai, X. (2018) High-precision Ca isotopic measurement using a large geometry high resolution MC-ICP-MS with a dummy bucket. J. Anal. At. Spectrom. 33, 1707-1719.

10.Wang, Z. and Becker, H. (2018) Molybdenum partitioning behavior and content in the depleted mantle: Insights from Balmuccia and Baldissero mantle tectonites (Ivrea Zone, Italian Alps). Chem. Geol. 499, 138-150.

11.Wang, Z., Becker, H., Liu, Y., Hoffmann, E., Chen, C., Zou, Z. and Li, Y. (2018a) Constant Cu/Ag in upper mantle and oceanic crust: Implications for the role of cumulates during the formation of continental crust. Earth Planet. Sci. Lett. 493, 25-35.

12.Wang, Z., Lazarov, M., Steinmann Lena, K., Becker, H., Zou, Z. and Geng, X. (2018b) The distribution of lead and thallium in mantle rocks: Insights from the Balmuccia peridotite massif (Italian Alps). Am. Mineral. 103, 1185–1199.

13.Wang, Z., Becker, H., 2017a. Chalcophile elements in Martian meteorites indicate low sulfur content in the Martian interior and a volatile element-depleted late veneer. Earth Planet. Sci. Lett. 463, 56-68.

14.Wang, Z., Becker, H., 2017b. Silver contents and Cu/Ag ratios in Martian meteorites and the implications for planetary differentiation. Geochim. Cosmochim. Acta 216, 96-114.

15.Wang, Z., Laurenz, V., Petitgirard, S., Becker, H., 2016. Earth's moderately volatile element composition may not be chondritic: Evidence from In, Cd and Zn. Earth Planet. Sci. Lett. 435, 136-146.

16.Wang, Z., Becker, H., 2015a. Abundances of Ag and Cu in mantle peridotites and the implications for the behavior of chalcophile elements in the mantle. Geochim. Cosmochim. Acta 160, 209-226.

17.Wang, Z., Becker, H., 2015b. Comment on “A non-primitive origin of near-chondritic S-Se-Te ratios in mantle peridotites: Implications for the Earth's late accretionary history” by König S. et al. [Earth Planet. Sci. Lett. 385 (2014) 110–121]. Earth Planet. Sci. Lett. 417, 164-166.

18.Wang, Z., Becker, H., 2015c. Fractionation of highly siderophile and chalcogen elements during magma transport in the mantle: Constraints from pyroxenites of the Balmuccia peridotite massif. Geochim. Cosmochim. Acta 159, 244-263.

19.Wang, Z., Becker, H., Wombacher, F., 2015d. Mass Fractions of S, Cu, Se, Mo, Ag, Cd, In, Te, Ba, Sm, W, Tl and Bi in Geological Reference Materials and Selected Carbonaceous Chondrites Determined by Isotope Dilution ICP-MS. Geostand. Geoanal. Res. 39, 185-208.

20.Wang, Z., Becker, H., 2014. Abundances of sulfur, selenium, tellurium, rhenium and platinum-group elements in eighteen reference materials by isotope dilution sector-field ICP-MS and negative TIMS. Geostand. Geoanal. Res. 38, 189-209.

21.Wang, Z., Becker, H., 2013. Ratios of S, Se and Te in the silicate Earth require a volatile-rich late veneer. Nature 499, 328-331.

22.Wang, Z., Becker, H. and Gawronski, T. (2013) Partial re-equilibration of highly siderophile elements and the chalcogens in the mantle: A case study on the Baldissero and Balmuccia peridotite massifs (Ivrea Zone, Italian Alps). Geochim. Cosmochim. Acta 108, 21-44.

23.Zeng, Q., Wang, Z., He, H., Wang, Y., Zhang, S., Liu, J., 2014. Multiple isotope composition (S, Pb, H, O, He, and Ar) and genetic implications for gold deposits in the Jiapigou gold belt, Northeast China. Mineral. Deposita 49, 1-20.

24.汪在聰,李勝榮,劉鑫,施娘華,初鳳友,佟景貴, 2007.中太平洋WX海山富鈷結殼磷酸鹽礦物學研究及成因類型分析.岩石礦物學雜誌26, 441-448.

25.汪在聰,李勝榮,申俊峰, 2008.河南省前河構造蝕變岩型金礦的矽卡岩化及其找礦意義.礦床地質27, 751-761.

26.汪在聰,劉建明,劉紅濤,曾慶棟,張松,王永彬, 2010.穩定同位素熱液來源示蹤的複雜性和多解性評述——以造山型金礦為例.岩石礦物學雜誌29, 577-590.

2023年5月，入選2023年“湖北青年五四獎章”獲獎者名單。