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副教授
王小明
发布人:发布时间:2017-05-04

姓名:王小明                     职称:副教授    

电话:17764085114     E-mail:wangxm338@mail.hzau.edu.cn

研究方向:

土壤化学与环境(土壤污染修复、磷素高效利用、土壤矿物化学)

个人简介

  土壤学农学博士,副教授,博士生导师。主要从事土壤矿物结构、形成-演化、元素界面生物-化学反应行为及环境效应等方面研究,为土壤污染绿色修复和磷肥资源高效利用提供科学依据。近年在ES&T、GCA、Appl. Catal. B-Environ.、ES-nano和SSSAJ等本领域主流期刊共发表论文50篇,其中一作或通讯论文23,总论文SCI他引625次,H指数15(web of science)。主持国家自然科学基金面上项目、青年项目、国家重点研发计划子课题、中国博士后科学基金各1项,参与国家自然科学重点基金和病虫草害绿色防控岗位科学项目各1项,授权发明专利1项,在国内外主流学术会议做口头报告20次、墙报7次,2016年获湖北省优秀博士学位论文奖。受邀担任Soil Sci. Soc. Am. J.、Appl. Clay Sci.、Environ. Sci.-Proc. Imp.、Appl. Geochem.、Bull. Environ. Contam. Toxicol.、ACS Omega等期刊审稿人,国家自然科学基金评审专家。编写土壤百科全书词条(无定形铁,游离铁,水铁矿)和农业百科全书词条(氧化铁,氧化铝)。

教育/工作经历

2018.06—至今 : 华中农业大学副教授

2015.072018.06 : 华中农业大学师资博士后

2015.08—2016.10 : 美国怀俄明大学生态系统科学与管理系博士后

2008.09—2015.06 : 华中农业大学资环学院土壤学专业博士学位

2014.07—2015.06  :  美国怀俄明大学国家公派联合培养博士

2004.09—2008.06 : 华中农业大学资环学院环境工程专业学士学位

获奖及专利

荣誉和奖励

2020年:华农资环学院“2020年青年教师教学技能竞赛”三等奖;第四届“华癸创新计划”导师;第三届铁环境化学及污染控制技术研讨会分会主持人;指导博士生应虹获“第三届铁环境化学及污染控制技术研讨会”研究生口头报告二等奖(202010)”。

2019年:资环学院“第十四届”青年教师讲课竞赛三等奖;指导本科生黄坤获“华中农业大学优秀学士学位论文”、博士生应虹获“2019土壤环境、土壤化学专委会”优秀学术报告二等奖(201907)。

2017年:“湖北省2016年优秀博士学位论文”;

2016年:“校2015年优秀博士学位论文”;“2016全国矿物科学与工程会议优秀分会论文奖”

2015年:“国家公派奖学金”

2013年:“博士研究生国家奖学金 

授权专利

王小明,应虹,黄坤,冯雄汉,严玉鹏,刘凡。一种用于去除三价砷和六价铬的施氏矿物,ZL201910958408.2,2020-08-26.

教学情况

本科生课程:“环境污染与土壤健康”(16学时)、“大气污染控制工程”(48学时)、“大气污染控制工程课程设计”(8学时)、“环境工程学实验”(40学时)

研究生课程 :“环境土壤化学”(30学时);“土壤矿物学”(6学时)

科学研究

在研项目

  1. 2020.11-2024.1,国家重点研发专项子课题(2020YFC1806803),多组分土壤互作界面污染物物化-生物耦合过程表征,62万(主持)

  2. 2020.01-2023.12,国家自然科学基金面上项目 (No. 41977021),中轻度污染农田土壤中重金属与磷素的形态转化特点与机制,61万 (主持)

  3. 2019- ,病虫草害绿色防控岗位,国家现代农业产业技术体系(CARS26)子课题,10万/年(主持)

  4. 2019.01-2021.12,新进教师科研启动专项 (No. 2662019QD015),过渡金属掺杂(高铁)绿锈的合成、结构表征及其表面吸附/氧化特性,20万(主持)

  5. 2021.1-2025.12,国家自然科学基金重点项目(No. 42030709),水旱轮作农田土壤中弱晶质氧化铁的形成演化及与环境元素交互作用机理(参与)

 已结题项目

  1. 2017.01-2019.12,国家自然科学青年基金 (No. 41601228),酸性矿山废水中施氏矿物的矿物学特性及其对As(V)和Cr(VI)的富集机制,20万 (主持)

  2. 2017.07-2019.06,广东省矿物物理与材料研究开发重点实验室开放基金 (No. GLMPM-26),酸性矿山废水环境中施氏矿物的形成与转化特性研究,4.0万 (主持)

  3. 2018.03-2018.12,学院学科建设人才培育项目,土壤中常见金属离子对绿锈形成与转化的影响及赋存机制,15万(主持)

  4. 2017.08,2017年“博士后国际交流计划”学术交流项目,3.0万 (主持)

  5. 2016.07-2018.07,博士后基金一等资助 (No. 2016M5907  00),土壤环境中绿锈的形成与转化及其对金属离子的富集机制,8.0万 (主持)

主要论文

一作和通讯作者论文

(1)Zhao W., Gu C., Ying H., Feng X., Zhu M., Wang M., Tan W., Wang X.* Fraction distribution of heavy metals and 1 its relationship with iron in polluted farmland soils around distinct mining areas. Applied Geochemistry, 2021. (Accepted)

(2)Ying H., Huang K., Feng X., Yan Y., Zhu M., Wang Z., Huang Q., Wang X.* As(III) adsorption-oxidation behavior and mechanisms on Cr(VI)-incorporated schwertmannite. Environmental Science: Nano, 2021, DOI: 10.1039/D1EN00104C

(3)Wang X.*, Ying H., Zhao W., Feng X., Tan W., Beyer K., Huang Q., Liu F., Zhu M*. Molecular-scale Understanding of Sulfate Exchange from Schwertmannite by Chromate versus Arsenate. Environmental Science & Technology, 2021. doi.org/10.1021/acs.est.0c07980

(4)Ying H., Feng X., Zhu M., Lanson B., Liu F., Wang X.* Formation and transformation of schwertmannite through direct Fe3+ hydrolysis under various geochemical conditions. Environmental Science: Nano, 2020, 7, 2385-2398

(5)Shen W. #, Wang X.#, Jia F.*, Tong Z., Sun H., Wang X., Song F., Ai Z.*, Zhang L.*, Chai B. Amorphization Enables Highly Efficient Anaerobic Thiamphenicol Reduction by Zero-valent Iron. Applied Catalysis B: Environmental, 2020, 264, 118550. (共同一作)

(6)Wang X., Phillips B. L., Boily J., Hu Y., Hu Z., Yang P., Feng X., Xu W., Zhu M*. Phosphate Sorption Speciation and Precipitation Mechanisms on Amorphous Aluminum Hydroxide. Soil Systems, 2019, 3, 20

(7) Wang X., Peng J., Liang X., Zhu M., Lanson B., Wang L., Liang X., Liu F., Tan W., Feng X*. Effects of Mn2+, Ni2+, and Cu2+ on the formation and transformation of hydrosulfate green rust: reaction processes and underlying mechanisms. ACS Earth and Space Chemistry, 2019, 3, 519-530

(8) Lan S.,# Wang X.# Yang P., Qin Z., Zhu M., Zhang J., Liu F., Tan W., Huang Q., Feng X*. The Catalytic Effect of AQDS as an Electron Shuttle on Mn(II) Oxidation to Birnessite on Ferrihydrite at Circumneutral pH. Geochimica et Cosmochimica Acta, 2019, 247: 175-190. (共同一作)

(9) Wang X., Wang Z., Peak D., Tang Y., Feng X., Zhu M*. Quantification of Coexisting Inner- and Outer-sphere Complexation of Sulfate on Hematite Surfaces. ACS Earth and Space Chemistry, 2018, 2: 387-398

(10) Wang X., Kubicki J. D., Boily J., Waychunas G., Hu Y., Feng X., Zhu M*. Binding Geometries of Silicate Species on Ferrihydrite Surfaces. ACS Earth and Space Chemistry, 2018, 2: 125-134.

(11)Wang X., Hu Y., Tang Y., Yang P., Feng X., Xu W., Zhu M*. Phosphate and Phytate Adsorption and Precipitation on Ferrihydrite Surfaces. Environmental Science: Nano, 2017, 4: 2193-2204

(12)Wang X., Peng J., Xu H., Tan W., Liu F., Huang Q., Feng X.* Influences and Mechanisms of As(V) Concentration and Environmental Factors on Hydrosulfate Green Rust Transformation. Acta Chimica Sinica-Chinese Edition, 2017, 75: 608-616

(13)Wang X., Li W., Koopal L. K. Zhu M., Xu W., Liu F., Zhang J., Li Q., Feng X.* Sparks D. Effects of Crystallite Size on the Structure and Magnetism of Ferrihydrite. Environmental Science: Nano, 2016, 3: 190−202

(14)Wang X., Lan S., Zhu M., Ginder-vogel M., Yin H., Liu F., Tan W., Feng X.* The Presence of Ferrihydrite Promotes Abiotic Formation of Manganese (Oxyhydr)oxides. Soil Science Society of America Journal, 2015, 79:1297–1305

(15)Feng X.,* Wang X., Zhu M., Koopal L. K., Xu H., Wang Y., Liu F. Effects of Phosphate and Silicate on the Transformation of Hydroxycarbonate Green Rust to Ferric Oxyhydroxides. Geochimica et Cosmochimica Acta, 2015, 171: 1–14 (导师一作)

(16)Wang X., Zhu M., Lan S., Ginder-vogel M., Liu F., Feng X.* Formation and Secondary Mineralization of Ferrihydrite in the Presence of Silicate and Mn(II). Chemical Geology, 2015, 415: 37−46

(17)Wang X., Gu C., Zhu M.*, Feng X.* Sulfate Local Coordination Environment in Schwertmannite. Environmental Science & Technology, 2015, 49: 10440−10448

(18)Wang X., Li W.,* Harrington R., Liu F., Parise J. B., Feng X.,* Sparks D. L. Effect of Ferrihydrite Crystallite Size on Phosphate Adsorption Reactivity. Environmental Science & Technology, 2013, 47: 10322-10331

(19)Wang X., Liu F., Tan W., Feng X.,* Koopal L. K. Transformation of Hydroxycarbonate Green Rust into Crystalline Iron (oxyhydr)oxides: Influences of Reaction Conditions and Underlying Mechanisms. Chemical Geology, 2013, 351: 57-65

(20)Wang X., Liu F., Tan W., Li W., Feng X.,* Sparks D. L. Characteristics of Phosphate Adsorption-Desorption onto Ferrihydrite: Comparison with Well-Crystalline Fe (Hydr)oxides. Soil Science, 2013, 178: 1-11

(21)王小明,杨凯光,孙世发,徐剑,李耀光,刘凡,冯雄汉*。水铁矿的结构、组成及环境地球化学行为.地学前缘,2011,18:340-347

(22)王小明孙世发,刘凡,谭文峰,胡红青,冯雄汉*。铁(氢)氧化物悬液中磷酸盐的吸附-解吸特性研究。地球化学,2012,4:89-98

(23)王小明,艾思含,董婷,刘凡,谭文峰,邱国红,冯雄汉*。人工合成绿锈GR(CO32-)的氧化晶质过程、特点及主要影响因素。土壤学报,2013,50:77-86

共同作者论文

(24)Wang X., Wang Q., Yang P., Wang X., Zhang L., Feng X., Zhu M., Wang Z. Oxidation of Mn(III) Species by Pb(IV) Oxide as a Surrogate Oxidant in Aquatic Systems. Environmental Science and Technology, 2020, 54, 14124−14133

(25)Ying C., Lanson B., Wang C., Wang X., Yin H., Yang Y., Tan W., liu F., Feng X. Highly enhanced oxidation of arsenite at the surface of birnessite in the presence of pyrophosphate and the underlying reaction mechanisms. Water Research, 2020, 187, 116420.

(26)Chen H., Tan W., Lv W., Xiong J. Wang X., Yin H., Fang L.* Molecular Mechanisms of Lead Binding to Ferrihydrite-Bacteria Composites: ITC, XAFS and μ-XRF Investigations. Environmental Science and Technology, 2020, 54, 4016-4025

(27)Lu Y., Hu S., Liang Z., Zhu M., Wang Z., Wang X., Liang Y., Dang Z., Shi Z. Incorporation of Pb(II) into hematite during ferrihydrite transformation. Environmental science: Nano, 2020, 7, 829-841

(28)Liao S., Wang X., Yin H., Post J., Yan Y., Tan W., Huang Q., Liu F., Feng X*. Effects of Al substitution on local structure and morphology of lepidocrocite and its phosphate adsorption kinetics. Geochimica et Cosmochimica Acta, 2020, 276, 109-121

(29)Wu Z., Lanson B., Feng X., Yin H., Qin Z., Wang X., Tan W., Chen Z., Wen W., Liu F*. Transformation of Ni-containing birnessite to tectomanganate: Influence and fate of weakly bound Ni(II) species. Geochimica et Cosmochimica Acta, 2020, 271, 96-115

(30)Liang X., Post J., Lanson B., Wang X., Zhu M., Liu F., Tan W., Feng X.*, Zhu G., Zhang X., Yoreo J. Coupled Morphological and Structural Evolution of δ-MnO2 to α-MnO2 through Multistage Oriented Assembly Processes: the Role of Mn(III). Environmental Science: Nano, 2020, 7, 238-249

(31)Liu L., Wang X., Zhu M., Ma J., Zhang J., Tan W., Feng X., Yin H.*, Liu F*. The speciation of Cd in Cd-Fe co-precipitates: Does Cd substitute for Fe in goethite structure? ACS Earth and Space Chemistry, 2019, 3, 2225-2236

(32)Tang Y., Wang X., Yan Y., Zeng H., Wang G., Tan W., Liu F., Feng X*. Effects of myo-inositol hexakisphosphate, ferrihydrite coating, ionic strength and pH on the transport of TiO2 nanoparticles in quartz sand. Environmental Pollution, 2019, 252, 1193-1201

(33)Hu Z., Jaisi D. P., Yan Y., Chen H., Wang X., Wan B., Liu F., Tan W., Huang Q., Feng X*. Adsorption and precipitation of myo-inositol hexakisphosphate onto kaolinite. European Journal of Soil Science, 2019, 71, 226-235

(34)Liang Y., Wang M.*, Xiong J., Hou J., Wang X., Tan W. Al-Substitution-Induced Defect Sites Enhance Adsorption of Pb2+ on Hematite. Environmental Science: Nano, 2019, 6: 1323-1331.

(35)Wang M., Tao Z., Xiong J., Wang X., Hou J., Koopal L. K., Tan W*. Formation and Morphology Evolution from Ferrihydrite to Hematite in the Presence of Tartaric Acid. ACS Earth and Space Chemistry, 2019, 3: 562-570.

(36)Zeng L., Wan B., Huang R., Yan Y., Wang X., Tan W., Liu F., Feng X*. Catalytic Oxidation of Arsenite and Reaction Pathways on the Surface of CuO Nanoparticles at a Wide Range of pHs. Geochemical Transactions. 2018, 19, 12.

(37)Yan Y., Wan B. Jaisi D. P., Yin H., Hu Z., Wang X., Chen C., Liu F., Tan W., Feng X*. Effects of Myo-inositol Hexakisphosphate on Zn(II) Sorption on γ-Alumina: A Mechanistic Study. ACS Earth and Space Chemistry, 2018, 2: 787-796

(38)Qin Z., Yin H., Wang X., Zhang Q., Lan S., Koopal L. K., Zheng L., Feng X., Liu F.* The preferential retention of VI Zn over IV Zn on birnessite during dissolution/desorption. Applied Clay Science. 2018, 161, 169-175

(39)Zhang Z., Goldstein H. L., Reynolds R., Hu Y., Wang X., Zhu M*. Phosphorus Speciation and Solubility in Aeolian Dust Deposited in the Interior American West. Environmental Science & Technology. 2018, 52, 2658-2667

(40)Yuan S*. Liu X., Liao W., Zhang P., Wang X., Tong M. Mechanisms of Electron Transfer from Structural Fe(II) in Reduced Nontronite to Oxygen for Production of Hydroxyl Radicals. Geochimica et Cosmochimica Acta. 2018, 223, 422-436 (SCI, IF/2017: 4.609)

(41)Lan S., Ying H., Wang X., Liu F., Tan W., Huang Q., Zhang J., Feng. X*. Efficient Catalytic As(III) Oxidation on the Surface of Ferrihydrite in the Presence of Aqueous Mn(II). Water Research, 2018, 128, 92-101 (SCI, IF/2017: 7.49)

(42)Lan S., Wang X., Xiang Q., Yin H., Qiu G., Liu F., Zhang J., Feng X*. Mechanisms of Mn(II) Catalytic Oxidation on Ferrihydrite Surfaces and the Formation of Manganese (Oxyhydr)oxides. Geochimica et Cosmochimica Acta. 2017, 211, 79-96 (SCI, IF/2017: 4.609)

(43)Gu C., Wang Z., Kubicki J. D., Wang X., Zhu M*. X‑ray Absorption Spectroscopic Quantification and Speciation Modeling of Sulfate Adsorption on Ferrihydrite Surfaces. Environmental Science & Technology, 2016, 50, 8067-8076 (SCI, IF/2017: 6.198)

(44)Gu C., Wang Z., Kubicki J. D., Wang X., Zhu M*. Corrections to: X‑ray Absorption Spectroscopic Quantification and Speciation Modeling of Sulfate Adsorption on Ferrihydrite Surfaces. Environmental Science & Technology, 2017. 51, 6608-6609 (SCI, IF/2017: 6.198)

(45)Yin H., Kwon K., Lee J., Shen Y., Zhao H., Wang X., Liu F., Zhang J. Feng X.* Distinct Effects of Al3+ Doping on the Structure and Properties of Hexagonal Turbostratic Birnessite: a Comparison with Fe3+ Doping. Geochimica et Cosmochimica Acta. 2017, 208, 268-284 (SCI, IF/2017: 4.609)

(46)Wan B., Yan Y., Zhu M., Wang X., Liu F., Feng X.* Quantitative and Spectroscopic Investigations of the Co-sorption of Myo-inositol Hexakisphosphate and Cadmium(II) on to Haematite. European Journal of Soil Science. 2017, 68, 374-383 (SCI, IF/2017: 3.475)

(47)易层,严玉鹏*,王小明,胡震,熊娟,刘凡,冯雄汉,谭文峰。天然有机质和金属离子在矿物表面的共吸附.农业环境科学学报,2018,37:1574-1583

(48)严玉鹏,唐亚东,万彪,王小明,刘凡,冯雄汉*。颗粒尺寸对纳米氧化物环境行为的影响。环境科学,2018,39:2983-2990

(49)严玉鹏,王小明,刘凡,冯雄汉*。有机磷与土壤矿物相互作用及其环境效应研究进展。土壤学报,2019,56:1290-1299

(50)严玉鹏,王小明,熊娟,王慧,胡震,刘凡,谭文峰,冯雄汉*。基于不同分析方法研究磷酸根在矿物表面吸附机制的进展。土壤学报,2020,57:22-35

 

国际和国内学术会议经历

国际学术会议

(1)Phosphate Sorption Speciation and Precipitation Mechanisms on Amorphous Aluminum Hydroxide. ASA-CSSA-SSSA International Annual Meeting in San Antonio, Texas, 2019, USA (口头报告)

(2)Effects of Mn2+, Ni2+ and Cu2+ on the formation and transformation of hydrosulfate green rust: reaction processes and underlying mechanisms. The 15th International Conference on the Biogeochemistry of Trace Elements, 2019, Nanjing, China. (会议墙报)

(3)Understanding Phosphate and Phytate Adsorption and Precipitation on Ferrihydrite Surfaces Using Differential Pair Distribution Function and Spectroscopic Analyses. The 3rd Asian Clay Conference in Guangzhou, China, 2016. (会议墙报)

(4)Sulfate Complexation on Hematite Surfaces. ACS Meeting in San Diego, CA, 2016. (口头报告)

Structural Characterization of Phosphate and Silicate Surface Species on Metal Oxides. ACS Meeting in San Diego, CA, 2016. (会议墙报)

(5)Sulfate Local Coordination Environment in the Schwertmannite Structure. ACS Meeting in Denver, CO, 2015. (口头报告)

(6)Effect of Ferrihydrite Crystallite Size on Structure and Physicochemical Properties. ACS Meeting in Denver, CO, 2015. (口头报告)

(7)Sulfate Local Atomic Environment in the Schwertmannite Structure. ASA, CSSA, and SSSA Annual Meeting in Long Beach, CA, 2014. (会议墙报)

(8)Effect of Ferrihydrite Crystallite Size on Phosphate Adsorption Reactivity. ASA, CSSA, and SSSA Annual Meeting in Long Beach, CA, 2014. (口头报告)

(9)Adsorption-Desorption Characteristics of Inorganic P onto Three Iron Oxides. 4th International Symposium Phosphorus Dynamics in the Soil-Plant Continuum (ISPDSPC4) office, Beijing, 2010. (会议墙报)

国内学术会议

(10)环境中施氏矿物的形成演化特性:直接Fe3+水解。中国土壤学会第十四次全国会员代表大会暨守护土壤健康,助力高质发展学术交流研讨会,哈尔滨,2020。(口头报告)

(11)同步辐射技术在土壤矿物界面反应中的应用。北京同步辐射装置学术年会,东莞,2019。(口头报告)

(12)磷素在几种常见铁/铝氧化物表面的吸附行为与机制。2019年中国土壤学会土壤环境专业委员会、土壤化学专业委员会联合学术研讨会,重庆,2019。(口头报告)

(13)Mn2+,Ni2+和Cu2+对硫酸盐绿锈形成与转化的影响:反应过程与主要机制。中国矿物岩石地球化学学会第17届学术年会,杭州,2019。(口头报告)

(14)硅酸根在水铁矿表面的吸附构型。2018年中国土壤学会土壤化学专业委员会学术研讨会,贵阳。(口头报告)

(15)Mn2+/Ni2+/Cu2+对硫酸盐绿锈形成与转化特性的影响及其赋存形态。中国土壤学会土壤环境专业委员会第二十次会议,合肥,2018。(口头报告)

(16)X 射线吸收和散射技术揭示水铁矿表面磷酸根和植酸固定机制。上海光源第七届用户学术年会(2017),厦门。(口头报告)

(17)硫酸根在赤铁矿表面的配位机制。中国土壤学会土壤化学专业委员会学术研讨会,南京,2017。(口头报告)

(18)Mn2+对硫酸盐绿锈形成-转化的影响和Mn赋存形态和机制。第九届全国环境化学大会,杭州,2017。(口头报告)

(19)磷酸根和植酸在水铁矿表面的吸附与沉淀。“中国土壤学会土壤环境专业委员会第十九次会议”暨“农田土壤污染与修复研讨会”,济南,2017。(口头报告)

(20)酸性矿山废水中硫酸根在铁氧化物表面和结构中的配位机制。2016年全国矿物科学与工程学术会议,北京,2016。(口头报告)

(21)X射线吸收和散色技术揭示水铁矿表面磷素固定机制。第一届环境铁化学和污染控制技术研讨会,上海,2016。(口头报告)

(22)第二届全国高能加速器(重大科技基础设施)战略研讨会暨用户年会,上海,2013。(会议墙报)

(23)绿锈GR1(CO32-)的氧化晶质过程、特点及主要影响因素。中国土壤学会土壤化学专业委员会学术研讨会,福州,2013。(口头报告)

(24)结合X射线吸收光谱和配对分布函数分析掺Si水铁矿的结构。北京同步辐射装置年会,宜昌,2012。(会议墙报)

(25)水铁矿与Mn(II)的相互作用,水铁矿的转化与表面催化。中国土壤学会土壤化学、土壤环境专业委员会研讨会,武汉,2011。(口头报告)

(26)三种常见铁(氢)氧化物悬液中磷酸盐的吸附-解吸特性。中国土壤学会土壤化学专业委员会学术研讨会,银川,2010。(口头报告)


学生培养情况

科技创新2017年第十二届全国环境友好科技竞赛、SRF项目4项、 “省创”项目1项;

华葵计划5人(熊宇、刘鑫雨,温珊,常梦涵,张瑞旋)

本科毕设12人(张岩、黄坤、龚继周、荆世超、黎学文、李京、李景铭、王兰昕、孙凤艳、刘祉辰、田珏、王雨枫)

研究生培养:

毕业研究生博士1人(协助指导):兰帅;硕士2人:徐欢欢、彭晶

在读研究生博士1人:应虹(协助指导);硕士9人:赵万通、顾丽婷、周子阳、黎学文、刘哲、邓婕、赵孟丽、曹薇薇、王云川


欢迎具有环境科学、土壤学、环境微生物学、地球化学等相关专业背景的学生报考硕士和申请博士,团队具有融洽的人际关系和良好的学术氛围,是你科研梦想启航的地方!

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