姓名
汪方跃
性别
男



出生年月
1982.8
职称
副研究员

行政职务
实验室秘书
研究生导师
硕导

E-mail
fywang@hfut.edu.cn
联系电话
**

通讯地址
安徽省合肥市屯溪路193号
邮编
230009

个人简介
汪方跃，安徽怀宁人。
教育与工作经历：
2000.9-2004.7 学士吉林大学地球科学学院专业: 资源勘查工程。
2004.9-2007.7 硕士西北大学地质学系专业: 地球化学研究方向：华北克拉通燕山期火山岩年代学和地球化学研究。
2007.9-2010.6 博士中国科学院广州地球化学研究所专业：地球化学方向: 华南中生代岩浆岩与成矿关系研究。
2010.7-2013.3 博士后中国科学技术大学地球和空间科学学院方向：长江中下游中生代埃达克岩与斑岩型铜金矿床。
2013.3-2014.6 特任副研究员中国科学技术大学地球和空间科学学院方向：长江中下游和中国东部沿海中生代岩浆岩与成矿。
2015.6-8月澳大利亚塔斯马尼亚大学CODES 访问****。
2014.6-至今合肥工业大学资环与环境学院副研究员。

研究领域
岩石地球化学，LA-ICP-MS在地学中的应用
岩浆岩与铜多金属成矿
中国东部中生代岩浆岩与成矿
俯冲带工厂
矿物地球化学

教学工作

目前指导本科毕业生11人，硕士研究生5名，在读硕士研究生3名。


科研工作
1、国家基金委重大项目之子项目：《板块俯冲过程中元素-同位素分异、岩浆作用与铜金成矿》，2011.01-2014.12，国家自然科学基金委，子项目负责人；
2、国家自然科学基金青年基金：《中国中东部含矿与不含矿高镁埃达克质岩源区及氧逸度特征对比研究》，2013.01-2015.12，国家自然科学基金委，项目负责人；
3、国家自然科学基金面上基金：《长江中下游宁镇地区早白垩世岩浆岩地球化学研究》，项目负责人，2014.1-2017.12，国家自然科学基金委，项目负责人；
4、青年创新基金：《长江中下游宁镇地区含矿埃达克岩成因研究》，2013.01-2014.12，教育部，项目负责人；
5、科技部重大专项“燕山期重大地质事件的深部过程与资源效应”，项目号：2016YFC0600-400之子项目“太平洋构造域的岩浆作用与成矿”（项目号2016YFC0600-404”），参与；
6、国家自然科学基金面上基金：《LA-(MC)-ICP-MS面扫描技术开发及应用》，批准号：**，2019.01-2022.12，国家自然科学基金委，项目负责人。

论著获奖

2021年：
1. Li, Y., Yuan, F., Jowitt, S. M., Wang, F.,Li, X., Deng, Y., Wang, Y., and Zhou, T., 2021, Molybdenite Re–Os, titanite and garnet U–Pb dating of the Magushan skarn Cu–Mo deposit, Xuancheng district, Middle–Lower Yangtze River Metallogenic Belt: Geoscience Frontiers, v. 12, no. 3, p. 101116.
2. Ge, C., Huo, J., Gu, H.-O., Wang, F., Sun, H., Li, X., Li, W., and Yuan, F., 2021, Tectonic discrimination and application based on convolution neural network and incomplete big data: Journal of Geochemical Exploration, v. 220, p. 106662.
3. Zhang, L., Chen, Z., Wang, F.*, and Zhou, T., 2021, Apatite geochemistry as an indicator of petrogenesis and uranium fertility of granites: A case study from the Zhuguangshan batholith, South China: Ore Geology Reviews, v. 128, p. 103886.
4. Shi, R., Zhao, J., Evans, N. J., Qin, K., Wang, F., Li, Z., Han, R., and Li, X., 2021, Temporal-spatial variations in Li-Fe mica compositions from the Weilasituo Sn-polymetallic deposit (NE China): implications for deposit-scale fluid evolution: Ore Geology Reviews, p. 104132.
5. Shen, J., Zhang, Y.-N., Yang, Y.-Z., Qin, L., He, Y., Liu, S.-A., Wang, F., and Ni, H., 2021, Molybdenum isotope tracing petrogenesis of adakitic rocks and associated ore-forming process: Geochimica et Cosmochimica Acta.In press
6. Zhang, L., Chen, Z., Wang, F.*, White, N. C., and Zhou, T., 2021, Release of Uranium from Uraninite in Granites Through Alteration: Implications for the Source of Granite-Related Uranium Ores: Economic Geology.doi: https://doi.org/10.5382/econgeo.4822
7. Zhang, L., Chen, Z., Wang, F.*, and Zhou, T., 2021, Whole-rock and biotite geochemistry of granites from the Miao’ershan batholith, South China: Implications for the sources of granite-hosted uranium ores: Ore Geology Reviews, v. 129, p. 103930.
8. Yang, W. X., Yan, D. P., Qiu, L., Wells, M. L., Dong, J. M., Gao, T., Zhang, Z, Mu, H. X., Wang, X. W and Wang, F.2021.Formation and forward propagation of the Indosinian foreland fold‐thrust belt and Nanpanjiang foreland basin in SW China.Tectonics, e2020TC006552.
9. 汪方跃,张文奇,段留安,吴杰,葛粲,孙贺,顾海欧,沈睿文,2021,东秦岭地区一种富稀土热液型钡解石的发现及其意义[J].岩石矿物学杂志,40(2):337~346.

2020年：
1. 闫海洋, 汪方跃*, and 葛粲, 2020, 低频LA-ICPMS分析技术应用型研究: 岩石矿物地球化学通报, v. 39, no. 1, p. 99-106.
2. Wang, S., Kuzmich, B., Hollings, P., Zhou, T., and Wang, F., 2020, Petrogenesis of the Dog Lake Granite Chain, Quetico Basin, Superior Province, Canada: Implications for Neoarchean crust growth: Precambrian Research, p. 105828.
3. Qiu, L., Yan, D. P., Yang, W. X., Cao, W., Ren, M., Gao, T., Dong, J., and Wang, F. Y., 2020, The timing of brittle deformation: An example from the Cenozoic faults in the Youjiang fold‐thrust belt in southwestern China: Geological Journal.
4. Nie, L., Zhou, T., White, N., Wang, F., and Song, Y., 2020, Zircon geochemistry of Edong granitoids in the Middle-Lower Yangtze Metallogenic Belt (Eastern China): Constraints on W-Cu-Fe skarn mineralization: Ore Geology Reviews, p. 103461.
5. Liu, G., Yuan, F., Deng, Y., Wang, F., White, N. C., Huizenga, J. M., Li, Y., Li, X., and Zhou, T., 2020, Ore-fluid geochemistry of the Hehuashan Pb–Zn deposit in the Tongling ore district, Anhui province, China: Evidence from REE and C–H–O isotopes of calcite: Ore Geology Reviews, v. 117, p. 103279.
6. Cheng, Z., Zhang, Z., Wang, Z., Wang, F., Mao, Q., Xu, L., Ke, S., Yu, H., and Santosh, M., 2020, Petrogenesis of transitional large igneous province: Insights from bimodal volcanic suite in the Tarim large igneous province: Journal of Geophysical Research: Solid Earth, v. 125, no. 5, p. e2019JB018382.
7. Yan, H., Wang, F.*, Gu, H.-O., Sun, H., and Ge, C., 2020, Geochemical and Sr-Nd-Pb-Hf Isotopic Characteristics of Muchen Pluton in Southeast China, Constrain the Petrogenesis of Alkaline A-Type Magma,minerals,v. 10, no. 1, p. 80.
8. 张文奇，汪方跃*. 2020. 扫描电镜组合式样品载物台. 专利号：ZL 2020 2 **.8. 实用新型专利
9. Lang, M., Cheng, Z., Zhang, Z., Wang, F., Mao, Q., and Santosh, M. J. J. o. E. S., 2020, Hisingerite in Trachydacite from Tarim: Implications for Voluminous Felsic Rocks in Transitional Large Igneous Province, v. 31, no. 5, p. 875-883.
10. Duan, Z., Gleeson, S. A., Gao, W.-S., Wang, F.-Y.,Li, C.-J., and Li, J.-W. J. O. G. R., 2020, Garnet U-Pb dating of the Yinan Au-Cu skarn deposit, Luxi District, North China Craton: Implications for district-wide coeval Au-Cu and Fe skarn mineralization, v. 118, p. 103310.
11. Xing, K., Shu, Q., Lentz, D. R., and Wang, F.,2020, Zircon and apatite geochemical constraints on the formation of the Huojihe porphyry Mo deposit in the Lesser Xing?ˉan Range, NE China: American Mineralogist: Journal of Earth Planetary Materials, v. 105, no. 3, p. 382-396.
12. 软件著作权：LA-ICPMS mapping处理软件V1.0；2020；葛粲、汪方跃等
13. 徐锦龙, 沈仕豪, 汪雅菲, 汪方跃. 中二叠统热水沉积新证据——以皖南 “嵇亭岭砾岩” 为例[J]. 沉积学报, 2020, 38(2): 284-296.

2019年：
1. 王辉, 汪方跃*, and 盛兆秋, 2019, LA-ICP-MS 分析中不同莫氏硬度矿物激光剥蚀行为及剥蚀速率研究: 岩石矿物学杂志, v. 38, no. 1, p. 113-120.
2. 王辉, 汪方跃*, 关炳庭, and 盛兆秋, 2019, 激光能量密度对 LA-ICP-MS分析数据质量的影响研究: 岩矿测试, v. 38, no. 6, p. 724-734.
3. 周涛发, 聂利青, 王世伟, 汪方跃, and 张千明, 2019, 长江中下游成矿带钨矿床, v. 35, no. 12, p. 3592-3608.
4. 聂利青, 周涛发, 汪方跃, 张千明, 张明, and 汪龙虎, 2019, 安徽庐枞矿集区东顾山钨矿床成矿流体来源与演化:来自H、O、S同位素和流体包裹体的证据: 岩石学报, v. 35, no. 12.
5. 葛粲, 汪方跃, 顾海欧, 管怀峰, 李修钰, and 袁峰, 2019, 基于卷积神经网络和火山岩大数据的构造源区判别: 地学前缘, v. 26, no. 4, p. 22-32.
6. Xiao, Q.-L., Zhou, T.-F., Wang, S.-W., Yuan, F., White, N. C., Wang, F.-Y., Xie, Z.-J., and Liu, J., 2019, Genesis of Chating Cu-Au deposit in the Middle-Lower Yangtze River Metallogenic Belt, Eastern China: Implications from magnetite and biotite geochemistry: Ore Geology Reviews, v. 106, p. 113-133.
7. Sun, W., Yuan, F., Jowitt, S. M., Zhou, T., Liu, G., Li, X., Wang, F., and Troll, V. R., 2019, In situ LA–ICP–MS trace element analyses of magnetite: genetic implications for the Zhonggu orefield, Ningwu volcanic basin, Anhui Province, China: Mineralium Deposita, v. 54, no. 8, p. 1243-1264.
8. Qiu, L., Yang, W.-X., Yan, D.-P., Wells, M. L., Qiu, J.-T., Gao, T., Dong, J.-M., Zhang, L., and Wang, F.-Y., 2019, Geochronology of early Mesozoic diabase units in southwestern China: metallogenic and tectonic implications: Geological Magazine, v. 156, no. 7, p. 1141-1156.
9. Li, Y., Feng, L., Kiseeva, E. S., Gao, Z., Guo, H., Du, Z., Wang, F.,and Shi, L., 2019, An essential role for sulfur in sulfide-silicate melt partitioning of gold and magmatic gold transport at subduction settings: Earth and Planetary Science Letters, v. 528.
10.Jin, S., Zhang, Z., Cheng, Z., Xie, Q., Fei, X., Santosh, M., and Wang, F., 2019, Compositions of olivine from the Wajilitag mafic-ultramafic intrusion of the Permian Tarim Large Igneous Province, NW China: Insights into recycled pyroxenite in a peridotite mantle source: Journal of Asian Earth Sciences, v. 171, p. 9-19.
11.Hu, J.-Q., Li, X.-W., Xu, J.-F., Mo, X.-X., Wang, F.-Y., Yu, H.-X., Shan, W., Xing, H.-Q., Huang, X.-F., and Dong, G.-C., 2019, Generation of coeval metaluminous and muscovite-bearing peraluminous granitoids in the same composite pluton in West Qinling, NE Tibetan Plateau: Lithos, v. 344, p. 374-392.
12.Gu, H.-O., Sun, H., Wang, F., Ge, C., and Zhou, T., 2019, A new practical isobaric interference correction model for the in situ Hf isotopic analysis using laser ablation-multi-collector-ICP-mass spectrometry of zircons with high Yb/Hf ratios: Journal of Analytical Atomic Spectrometry, v. 34, p. 1223-1232.
13. Chen, X., Richards, J. P., Liang, H., Zou, Y., Zhang, J., Huang, W., Ren, L., and Wang, F., 2019, Contrasting arc magma fertilities in the Gangdese belt, Southern Tibet: Evidence from geochemical variations of Jurassic volcanic rocks: Lithos, v. 324-325, p. 789-802.

2018年：
1. Xiao, X., Zhou, T. F., White, N. C., Zhang, L. J., Fan, Y., Wang, F. Y., and Chen, X. F., 2018. The formation and trace elements of garnet in the skarn zone from the Xinqiao Cu-S-Fe-Au deposit, Tongling ore district, Anhui Province, Eastern China. Lithos s 302–303, 467-479.
2. Ren, Z., Zhou, T., Hollings, P., White, N. C., Wang, F., and Yuan, F., 2018. Trace element geochemistry of molybdenite from the Shapinggou super-large porphyry Mo deposit, China. Ore Geology Reviews 95, 1049-1065.
3. Shen, J., Qin, L., Fang, Z., Zhang, Y., Liu, J., Liu, W., Wang, F., Xiao, Y., Yu, H., and Wei, S., 2018. High-temperature inter-mineral Cr isotope fractionation: A comparison of ionic model predictions and experimental investigations of mantle xenoliths from the North China Craton. Earth and Planetary Science Letters 499, 278-290.
4. Duan, L. A., Yang, X., Deng, J., Wang, F., and Insung, L., 2018. Mineralization, Geochemistry and Zircon U-Pb Ages of the Paodaoling Porphyry Gold Deposit in the Guichi Region, Lower Yangtze Metallogenic Belt, Eastern China. Acta Geologica Sinica(English Edition) 92, 706-732.
5. 葛粲,汪方跃,李永东,李晓晖,李修钰,周宇章,袁峰,李建设,陆三明. 2018. 基于GEOROC大数据分析地壳厚度地球化学指标. 岩石学报, 34(11): 3179-3188
6. Dai, H., Liu, Y., Wang, J. J., Nie, Y. G., Sun, Y. X., Wang, M. D., Wang, D. Y., Yang, Z., Cheng, L., Wang, J., Weng, J., Wang, Q. Q., Wang, F. Y., Wu, L. J., Zhao, G. P., and Xu, A., 2018. Graphene oxide antagonizes the toxic response to arsenic via activation of protective autophagy and suppression of the arsenic-binding protein LEC-1 in Caenorhabditis elegans. Environ.-Sci. Nano 5, 1711-1728.
7. 葛粲, 顾海欧, 汪方跃, 李修钰, 周宇章, 袁峰.2018. 基于数据密度确定分布区域的方法：以TAS图解分析为例. 地球科学, 53(4):1240-1253
2017年：
1. 汪方跃*, 葛粲, 宁思远, 聂利青, 钟国雄, White, N., 2017. 一个新的矿物面扫描分析方法开发和地质学应用. 岩石学报33, 3422-3436.
2. 宁思远, 汪方跃*, 薛纬栋, 周涛发, 2017. 长江中下游铜陵地区宝山岩体地球化学研究. 地球化学46, 397-412.
2016年：
1. He Z, Huang F, Yu H, Xiao Y, Wang F,Li Q, Xia Y, Zhang X. 2016. A Flux‐Free Fusion Technique for Rapid Determination of Major and Trace Elements in Silicate Rocks by LA‐ICP‐MS[J]. Geostandards and Geoanalytical Research,, 40(1): 5-21.
2015年：
1. 刘军锋,李超,李贺,孙卫东,汪方跃*，2015.岩石学报.四会岩体: 一个潜在的含钼铜矿化岩体，31(3): 791-801
2. 张力钰,刘盛遨,赵盼捞,汪方跃，2015.岩石学报. 宁镇地区成矿斑岩与铁镁质包体铜同位素研究，31(7): 1908-1916
2014年以前:
1. Wang, F.*,Liu, S.-A., Li, S., Akhtar, S., and He, Y., Zircon U–Pb ages, Hf–O isotopes and trace elements of Mesozoic high Sr/Y porphyries from Ningzhen, eastern China: Constraints on their petrogenesis, tectonic implications and Cu mineralization[J]. Lithos, 2014, 200–201, p. 299-316.
2. Wang, F.Y*., S.-A. Liu, S. Li, et al., Contrasting zircon Hf–O isotopes and trace elements between ore-bearing and ore-barren adakitic rocks in central-eastern China: Implications for genetic relation to Cu–Au mineralization[J]. Lithos, 2013. 156–159(0):97-111.
3. Ding, X., Sun, W. D., Wang, F. Y.et al., Single-grain mica Rb-Sr isochron ages and mineral chemistry for the Weishan pluton in Hunan province and implications on petrogenesis and mineralization of Mesozoic composite granite in South China[J], Acta Petrologica Sinica, 28(12), 3823-3840.
4. Duan L. A., Yang X. Y., Wang F. Y.,et al., Geochemistry and zircon U-Pb age of ore-bearing porphyry in the Paodaoling gold deposit in Guichi, Middle-Lower Yangtze metallogenic belt[J], Acta Petrologica Sinica, 28(10), 3241-3254.
5. Li, C.-Y., H. Zhang, F.-Y. Wang, et al., The formation of the Dabaoshan porphyry molybdenum deposit induced by slab rollback[J]. Lithos, 2012. 150(0):101-110.
6. Wang, F.Y., C.-Y. Li, M.-X. Ling, et al., Geochronology of the Xihuashan Tungsten Deposit in Southeastern China: Constraints from Re–Os and U–Pb Dating[J]. Resource Geology, 2011. 61(4):414-423.
7. Wang, F.Y., M.X. Ling, X. Ding, et al., Mesozoic large magmatic events and mineralization in SE China: oblique subduction of the Pacific plate[J]. International Geology Review, 2011. 53(5-6):704-726.
8. Ling, M.X.,F.Y. Wang, X. Ding, et al., Different origins of adakites from the Dabie Mountains and the Lower Yangtze River Belt, eastern China: geochemical constraints[J]. International Geology Review, 2011. 53(5-6):727-740.
9. Li, C.-Y., F.Y. Wang, X.-L. Hao, et al., Formation of the world's largest molybdenum metallogenic belt: a plate-tectonic perspective on the Qinling molybdenum deposits[J]. International Geology Review, 2011. 54(9):1093-1112.
10. Ling, M.-X.,F.Y. Wang, X. Ding, et al., Cretaceous ridge subduction along the Lower Yangtze River Belt, Eastern China[J]. Economic Geology, 2009. 104:303-321.
11. Wang, F.Y., Gao, S., Niu, B., and Zhang, H., Geochemistry of Dabeigou Basalt in Chengde Basin, Hebei Province and Constraints on Lithospheric Mantle Thinning of North China Craton: Earth Science Frontiers[J], 2007, 14, 98-108.