个人简历
姚卓森,博士,1990年生于山西长治,高中毕业于山西大学附属中学,2012年于中山大学获得学士学位,2018年于中科院地质与地球物理研究所获得博士学位,导师为秦克章研究员,随后在加拿大卡尔顿大学进行博士后研究工作,合作导师为James Mungall教授,回国后入职中国地质大学(武汉)资源学院。主要从事岩浆铜镍硫化物矿床、层状岩体的成矿作用及相应岩浆过程的研究,重点通过热力学模拟、流体动力学和地球化学动力学等不同的维度来探究和扩展岩浆矿床的成矿模型。目前第一作者论文11篇,主要包括Nature Communications (2)、EPSL、JGR-Solid Earth (2)、GCA、ESR、Journal of Petrology、American Mineralogist等国际知名地学期刊。曾担任Nature Communications, Geology, Journal of Petrology, Earth-Science Reviews, Economic Geology, Mineralium Deposita, Precambrian Research, Contributions to Mineralogy and Petrology, Ore Geology Reviews, Frontiers in Earth Science等国际地学刊物的审稿人,德国研究基金会的项目申请评阅人,西澳大学博士论文评阅人和答辩委员。
Researchgate: https://www.researchgate.net/profile/Yao-Zhuosen
Google Scholar: https://scholar.google.com/citations?user=NlbowO4AAAAJ&hl=zh-CN&oi=ao
加入我们: 欢迎优秀青年学子(高年级本科生、硕士生、博士生及博士后)加入我们课题组!
希望你踏实、勤奋、敏学、好问、积极、乐观、有进取心,“志存高远、脚踏实地”,对事物有一定的逻辑分析和思考能力,有较好的英语写作和沟通能力(以便于推荐至海外一流科研团队和实验室开展交流访问),善于讲“故事”,在学校中有较为丰富的辩论或PPT汇报经历!
我会努力搭建一个团结平等、互帮互助、协同创新、昂扬向上的课题组,鼓励你在日常学习中不断寻找自身知识体系中“自然生长”的创新点,并全力支持你开展相关研究工作,会保证两周一次、每次一小时左右的一对一交流时间,会鼓励并帮助你参加国际会议、交流访学、联合培养等事务,会尽力为你创造一个良好的科研环境,经过几年的接触和培养,希望能帮助你成长为一个看待事物更透彻、逻辑思维更缜密、专业认识更深入、科研能力更完备、沟通交流更自信的硕、博士毕业生!(“更好的自己”)
目前处于课题组搭建阶段,所以更加希望你能在以下某一方面具备卓越的能力:
1. 扎实的岩矿鉴定、镜下观察能力,熟悉构造、矿相学等相关知识,地学基础牢靠;
2. 良好的数学物理基础,有一定的编程能力,会使用一些科学编程软件;
3. 极强的动手能力,心灵手巧,善于设计实验装置,能快速组装或拆卸仪器;
4. 对数据挖掘、大数据处理、机器学习等新兴的研究方法感兴趣;
5. 思维开阔,想法新颖,有独特的知识体系架构或学科交叉背景
希望我们有缘相识,成为彼此攀爬科研高峰或探知缤纷世界的同路人。联系时请将详细的个人简历发送至 yaozhuosen@cug.edu.cn
代表性国际SCI论文:
[1] Yao, ZS., Mungall, J.E., 2022. Magnetite layer formation in the Bushveld Complex of South Africa. Nature Communications, 13, 416. (IF=14.919, 自然子刊)
[2] Yao, Z.S., Mungall, J.E., Jenkins MC. 2021. The Rustenburg Layered Suite formed as a stack of mush with transient magma chambers. Nature Communications, 12, 505. (IF=14.919, 自然子刊)
[3] Yao, Z.S., Mungall, J.E., 2020. Flotation mechanism of sulphide melt on vapour bubbles in partially molten magmatic systems. Earth and Planetary Science Letters, 542, 116298. (IF=5.255, 自然指数期刊)
[4] Yao, Z.S., Mungall, J.E., 2021. Linking the Siberian flood basalts and giant Ni-Cu-PGE sulfide deposits at Norilsk. Journal of Geophysical Research: Solid Earth, 126, e2020JB020823. (IF=3.848, 自然指数期刊)
[5] Yao, Z.S., Qin, K.Z., Qin, W., Xue, S.C., 2019. Weak B-type olivine fabric induced by fast compaction of crystal mush in a crustal magma reservoir. Journal of Geophysical Research: Solid Earth, 124, 3530-3556. (IF=3.848, 自然指数期刊)
[6] Yao, Z.S., Mungall, J.E., 2021. Kinetic controls on the sulphide mineralization of komatiite-associated Ni-Cu-(PGE) deposits. Geochimica et Cosmochimica Acta, 305, 185-211. (IF=5.010, 自然指数期刊)
[7] Yao, Z.S., Mungall, J.E., 2022. Transport and deposition of immiscible sulfide liquid during lateral magma flow. Earth-Science Reviews, 227, 103964. (IF=12.413, 地学top期刊)
[8] Yao, Z.S., Mungall, J.E., Qin, K.Z., 2019. A preliminary model for the migration of sulfide droplets in a magmatic conduit and the significance of volatiles. Journal of Petrology, 60, 2281-2316. (IF=4.515, 岩石学top期刊)
[9] Yao, Z.S., Qin, K.Z., Mungall, J.E., 2018. Tectonic controls in Ni and Cu contents of primary mantle-derived magmas for the formation of magmatic sulfide deposits. American Mineralogist, 103: 1545-1567. (IF=3.003, 矿物学top期刊)
[10] Yao, Z.S., Qin, K.Z., Xue, S.C., 2017. Kinetic processes for plastic deformation of olivine in the Poyi ultramafic intrusion, NW China: Insights from the textural analysis of a ~1700 m fully cored succession. Lithos, 284-285: 462-476. (IF=4.004, 岩石学知名期刊)
[11] Yao, Z.S., Qin, K.Z., Xue, S.C., 2017. Genetic relationship between deformation and low-Ca content in olivine from magmatic systems: evidence from the Poyi ultramafic intrusion, NW China. Mineralogy and Petrology, 111: 909-919. (IF=1.708, 岩石学期刊)
[12] Barnes, S.J., Yao, Z.S., Mao, Y.J., Jesus, A.P., Yang, S.H., Taranovic, V., Maier, W.D., 2023. Nickel in olivine as an exploration indicator for magmatic Ni-Cu sulfide deposits: a data review and re-evaluation. American Mineralogists, 108: 1-17.
[13] Chen, C., Yao, Z.S., Wang, Y.C., 2022. Partitioning behaviors of cobalt and manganese along diverse melting paths of peridotitic and MORB-like pyroxenitic mantle. Journal of Petrology, 63, egac021.
[14] Wang, Z.J., Yao, Z.S., Jin, Z.M., Wang, Y.N., 2023. Experimental investigation on the transport of sulfide driven by melt-rock reaction in partially molten peridotite. Journal of Geophysical Research: Solid Earth, 128, 2022JB026065.
[15] Jenkins, M.C., Mungall, J.E., Zientek, M.L., Costin, G., Yao, Z.S., 2021. Origin of the J-M Reef and lower banded series, stillwater complex, Montana, USA. Precambrian Research, 367, 106457.
[16] Chen, C., Su, B.X., Wang, Y.C., Uysal, I., Yao, Z.S., 2021. Mantle melting models of the Kizildag ophiolite in SE Turkey: Two types of partial melting processes in the oceanic upper mantle of southern Neo-Tethys. Lithos, 398-399, 106348.
[17] Chen, C., Wang, Y.C., Tan, W., Yao, Z.S., 2021. Origin of chromite nodules in podiform chromitite from the Kizildag ophiolite, southern Turkey. Ore Geology Reviews, 139, 104443.
[18] Kang, Z., Qin, K.Z., Mao, Y.J., Tang, D.M., Yao Z.S., 2020. The formation of a magmatic Cu-Ni sulfide deposit in mafic intrusions at the Kalatongke, NW China: Insights from amphibole mineralogy and composition. Lithos, 352-353, 105317.
[19] Xue, S.C., Li, C.S., Qin, K.Z., Yao, Z.S., Ripley, E.M., 2018. Sub-arc mantle heterogeneity in oxygen isotopes: evidence from Permian mafic-ultramafic intrusions in the Central Asian Orogenic Belt. Contributions to Mineralogy and Petrology, 173, 94.
[20] Tian, H.C., Yang, W., Li, S.G., Wei, H.Q., Yao, Z.S., Ke, S., 2019. Approach to trace hidden paleo-weathering of basaltic crust through decoupled Mg-Sr and Nd isotopes recorded in volcanic rocks. Chemical Geology, 509, 234-248.
[21] Xue, S.C., Li, C.S., Wang, Q.F., Ripley, E.M., Yao, Z.S., 2019. Geochronology, petrology and Sr-Nd-Hf-S isotope geochemistry of the newly discovered Qixin magmatic Ni-Cu sulfide prospect, southern Central Asian Orogenic Belt, NW China. Ore Geology Reviews, 111, 103002.
[22] Mole, D.R., Barnes, S.J., Yao, Z.S., White, A.R., Maas, W.R., Kirkland, C.L., 2017. The Archean Fortescue Large Igneous Province: A result of komatiite contamination by a distinct Eo-Paleoarchean crust. Precambrian Research, 310: 365-390.
[23] Lu, G.M., Cawood, P.A., Spencer, C.J., Bekker, A., Xu, Y.G., Yao, Z.S., Wang, W., 2023. Contrasting topography of Rodinia and Gondwana recorded by continental-arc basalts. Lithos, 442-443, 107094.
[24] Xue, S.C., Niu, Y.Y., Yao, Z.S., Wang, L.Y., Zhang, X.H., Wang, Q.F., 2023. Predicting olivine formation environments using machine learning and implications for magmatic sulfide prospecting. American Mineralogists, accepted.
专著:
姚卓森, 2023. 岩浆铜镍硫化物矿床成矿过程定量化模型的初步构建. 北京:中国学术期刊电子杂志社有限公司, ISBN: 978-7-83014-085-4.
教育经历
[1] 2012.9-2018.6
中国科学院地质与地球物理研究所
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矿物学、岩石学、矿床学
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博士学位
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博士研究生毕业
导师:秦克章研究员 博士论文:岩浆铜镍硫化物矿床成矿过程定量化模型的初步构建
[2] 2008.9-2012.6
中山大学
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地质学
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学士学位
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大学本科毕业
导师:王正海副教授
工作经历
[1] 2018.7-2021.9
卡尔顿大学
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地球科学学院
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博士后
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合作导师:James Mungall教授
研究方向
[1] 岩浆铜镍硫化物矿床的成矿动力学过程,地幔部分熔融、围岩混染、硫化物的运移、沉降和汇聚等,以地球化学为基础,更多从物理角度来看待岩浆成矿作用
[2] 层状岩体的成岩成矿过程,岩浆演化、火成岩岩浆作用
[3] 岩浆的流体动力学过程
[4] 元素在岩浆中的扩散、矿物生长等地球化学动力学过程
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