刘承帅
文章来源:    发布时间:2020-11-23      【字号:

 


姓名:刘承帅
性别:男
学历:博士研究生
职称:研究员,博士生导师,环境地球化学国家重点实验室副主任
地址:贵州省贵阳市观山湖区林城西路99号;550081
 
E-mail: liuchengshuai@vip.gyig.ac.cn


简历:

刘承帅19787月出生,博士、研究员、博士生导师、国家自然科学杰出青年基金获得者、国家重点研发计划项目首席科学家,担任环境地球化学国家重点实验室副主任。2001年武汉大学学士、2007年中科院广州地化所博士、2011年香港大学博士后、2014年美国爱荷华大学访问学者。主持包括国家重点研发计划、NSFC-广东联合重点、中科院前沿重点等在内的科研项目20余项;发表论文140多篇,其中SCI收录120多篇(第1/通讯50多篇),SCI他引3000多次,高引指数31;申请发明专利31件,其中授权16件,5件转让。

研究方向:
元素环境地球化学 
1)元素迁移转化及稳定同位素示踪 
    主要兴趣集中于地表金属元素环境地球化学行为及其调控,包括:环境矿物表面/结构中金属赋存特征及其转化机制;土壤介质与重金属相互作用机制及其环境效应;金属元素区域性迁移行为及其金属稳定同位素示踪。 
2)土壤重金属污染控制与修复 
 
     ①土壤重金属活性调控及风险控制;农田土壤重金属高效钝化材料研发与应用;场地土壤重金属晶体结构化固定与资源化利用处置;
区域土壤污染控制与风险防控。

承担科研项目情况:
1)国家重点研发计划项目,“场地土壤阳离子态重金属活性钝化新型功能材料研发”(2020YFC1808500),2020.11-2023.12,主持,在研;
 
2NSFC-广东联合基金重点项目,南岭矿区土壤重金属结构分异特征与污染来源解析 (U1701241)2018.1-2021.12,主持,在研; 
3)国家重点研发计划课题,金属氧化物与重()金属间的氧化还原固定于去除技术研发” (2017YFD0801002)2017.7-2020.12,主持,已结题; 
4)中国科学院“西部之光”交叉团队项目,“喀斯特关键带重金属循环与环境效应”,2020.1-2022.12,主持,在研; 
5)中国科学院前沿科学重点研究项目,基于结构分异的喀斯特矿区土壤重金属污染行为机制”( QYZDB-SSW-DQC046)2017.5-2022.5,主持,在研; 
6)国家自然科学基金面上项目,“Fe(II)催化铁()氧化物矿物相重组耦合重金属环境行为机制研究(41673135)2017.1-2020.12,主持,已结题; 
7)农业部公益性行业科研专项经费项目课题,农产品农药残留降解关键技术集成研究与示范”(201503107-4)2015.1-2020.12,主持,已结题; 
8)国家自然科学基金创新研究群体项目,“生物地球化学”(41921004),2020.1-2024.12,骨干成员,在研; 
9)国家自然科学基金面上项目,“土壤氧化铁表面硫的转化过程机制及其重金属脱毒效应” (41171364)2012.1-2015.12
,主持,已结题;
10)广东省应用型科技研发资金重大专项,“工业场地污染土壤资源化处置技术研发与成果转化”,2015.1-2018.12,主持,已结题。

社会任职:
(1)      中国土壤学会,理事; 
(2)      中国植物营养与肥料学会,理事; 
(3)      中国微生物学会地质微生物学专委会,委员 
(4)      中国矿物岩石地球化学学会青年委员会,委员; 
(5)     广东省土壤学会,常务理事。

获奖及荣誉:
(1)      国家“万人计划”青年拔尖人才; 
(2)      中科院高层次引进人才; 
(3)      广东“特支计划”科技创新领军人才; 
(4)      广东省自然科学杰出青年基金获得者; 
(5)      中国土壤学会优秀青年学者奖; 
(6)      21届全国发明展览会金奖一种巯基-铁基复合改性粘土及其制备方法 
(7)      参与获国家科技进步二等奖“稻田镉砷污染阻控关键技术与应用”; 
(8)    参与获省部级科技奖一等奖3项。

代表论著:
[1]    Liu CS, Massey MS, Latta DE, Xia YF, Li FB*, Gao T, Hua J, Fe(II)-induced transformation of iron minerals in soil ferromanganese nodules. Chemical Geology, 2020, 559, 119901.  
[2]    Liu YH, Gao T, Xia YF, Wang ZR, Liu CS*, Li SH, Wu QQ, Qi M, Lv YW, Using Zn isotopes to trace Zn sources and migration pathways in paddy soils around mining area. Environmental Pollution, 2020, 267, 115616. 
[3]    Ding W, Tong H, Zhao D, Zheng HL, Liu CS*, Li JJ, Wu F*, A novel removal strategy for copper and arsenic byphotooxidation coupled with coprecipitation: Performance and mechanism. Chemical Engineering Journal, 2020, 401, 126102. 
[4]    Liang S, Zhu LY, Hua J, Duan WJ, Yang PT, Wang SL, Wei CH, Liu CS*, Feng CH*, Fe2+/HClO reaction products produces FeIVO2+: An enhanced advanced oxidation process. Environmental Science & Technology, 2020, 54, 6406-6414.  
[5]    Xia YF#, Gao T#, Liu YH, Wang ZR, Liu CS*, Wu QQ, Qi M, Lv YW, Li FB, Zinc isotope revealing zinc’s sources and transport processes in Karst region. Science of the Total Environment, 2020, 724, 138191. 
[6]    Tong H, Liu CS*, Hao LK, Swanner ED, Chen MJ, Li FB, Xia YF, Liu YH, Liu YN, Biological Fe(II) and As(III) Oxidation Immobilizes Arsenic in Micro-oxic Environments. Geochimica et Cosmochimica Acta, 2019, 265, 96-108. 
[7]    Liu CS#, Gao T#, Liu YH, Liu JY, Li FB*, Chen ZW, Li YZ, Lv YW, Song ZY, Reinfelder JR, Huang WL, Isotopic fingerprints indicate distinct strategies of Fe uptake in rice. Chemical Geology, 2019, 524, 323-328. 
[8]    Wu F, Tang YY, Lu XW, Liu CS*, Lv YH, Tong H, Ning ZP, Liao CZ, Li FB, Simultaneous immobilization of Zn(II) and Cr(III) in spinel crystals from beneficial utilization of waste brownfield site soils. Clays and Clay Minerals, 2019, 67(4), 315-324. 
[9]    Shi TR, Ma J*, Zhang YY, Liu CS*, Hu YB, Gong YW, Wu X, Ju TN, Hou H, Zhao L, Status of lead accumulation in agricultural soils across China (1979-2016). Environment International, 2019, 129, 35-41. 
[10]Hua J, Liu CS*, Li FB, Chen MJ, Zhu ZK, Wei ZQ, Chen MJ, Gao T, Qiu GH, Effects of Rare Earth Elements’ Physicochemical Properties on Their Stabilization during the Fe(II)aq-induced Phase transformation of Ferrihydrite. ACS Earth and Space Chemistry, 2019, 3, 895-904.  
[11]Liu CS, Chen MJ, Li FB*, Tao L, Lin J, Gao T, Tong H, Liu YH, Long SQ, Wu F, Xia YF, Stabilization of Cd2+/Cr3+ during aqueous Fe(II)-induced recrystallization of Al-substituted goethite. Soil Science Society of America Journal, 2019, 83, 483-491. 
[12]Ding W, Xu J, Chen T, Liu CS*, Li JJ, Wu F*, Co-oxidation of As(III) and Fe(II) by oxygen through complexation between As(III) and Fe(II)/Fe(III) species. Water Research, 2018, 143, 599-607. 
[13]Gao T, Ke S, Wang SJ, Li FB, Liu CS*, Lei J, Liao CZ, Wu F, Contrasting Mg isotopic compositions between Fe-Mn nodules and surrounding soils: Accumulation of light Mg isotopes by Mg-depleted clay minerals and Fe oxides. Geochimica et Cosmochimica Acta, 2018, 237, 205-222.  
[14]Liao CZ, Su MH, Ma SS, Shih KM*, Feng Y, Liu CS*, Ho YK, Immobilization of Lead in Cathode Ray Tube Funnel Glass with Beneficial Use of Red Mud for Potential Application in Ceramic Industry. ACS Sustainable Chemistry & Engineering, 2018, 6, 14213-14220. 
[15]Tong H, Chen MJ, Li FB, Liu CS*, Li B, Qiao JT, Effects of humic acid on pentachlorophenol biodegrading microorganisms elucidated by stable isotope probing and high-throughput sequencing approaches. European Journal of Soil Science, 2018, 69, 380-391.  
[16]Liu CS, Chang CY, Fei YH, Li FB*, Wang Q, Zhai GS, Lei J, Cadmium accumulation in edible flowering cabbages in the Pearl River Delta, China: Critical soil factors and enrichment models. Environmental Pollution, 2018, 233, 880-888.  
[17]Chen MJ, Tong H, Li FB, Liu CS*, Lan Q, Liu CP, The effect of electron donors on the dechlorination of pentachlorophenol (PCP) and prokaryotic diversity in paddy soil. European Journal of Soil Biology, 2018, 86, 8-15. 
[18]Tong H, Chen MJ, Li FB, Liu CS*, Liao CZ, Changes in the microbial community during repeated anaerobic microbial dechlorination of pentachlorophenol. Biodegradation, 2017, 28, 219-230.
[19]Liao CZ, Tang YY, Lee PH., Liu CS*, Shih KM*, Li FB, Detoxification and immobilization of chromite ore processing residue in spinel-based glass-ceramic. Journal of Hazardous Materials, 2017, 321, 449-455. 
[20]Liu CS, Zhu ZK, Li FB*, Liu TX, Liao CZ, Lee JJ, Shih KM, Tao L, Wu YD, Fe(II)-induced phase transformation of ferrihydrite: The inhibition effects and stabilization of divalent metal cations. Chemical Geology, 2016, 444, 110-119.
[21]Liao CZ, Tang YY, Liu CS*, Shih KM, Li FB, Double-Barrier Mechanism for Chromium Immobilization: A Quantitative Study of Crystallization and Leachability. Journal of Hazardous Materials, 2016, 311, 246-253. 
[22]Tong H, Hu M, Li FB*, Liu CS*, Chen MJ, Biochar enhances the microbial and chemical transformation of pentachlorophenol in paddy soil. Soil Biology & Biochemistry, 2014, 70, 142-150.  
[23]Chen MJ, Liu CS*, Li FB, Zhai GS, Liu H*, Liu CP, Yu WM, Correlations between Soil Geochemical Properties and Fe(III) Reduction Suggest Microbial Reducibility of Iron in Different Soils from Southern China. Catena, 123 (2014) 176-187. 
[24]Chen MJ, Cao F, Li FB*, Liu CS*, Tong H, Wu HJ, Hu M, Anaerobic Transformation of DDT Related to Iron(III) Reduction and Microbial Community Structure in Paddy Soils. Journal of Agricultural and Food Chemistry, 61 (2013) 2224-2233.  
[25]Chen MJ, Shih K, Hu M, Li FB*, Liu CS*, Wu WJ, Tong H, Biostimulation of Indigenous Microbial Communities for Anaerobic Transformation of Pentachlorophenol in Paddy Soils of Southern China. Journal of Agricultural and Food Chemistry, 60 (2012) 2967-2975. 
[26] Liu H, Liang MY, Liu CS*, Gao YX, Zhou JM, Catalytic degradation of phenol in sonolysis by coal ash and H2O2/O3. Chemical Engineering Journal, 2009, 153, 131-137.
[27]Liu CS, Shih K*, Wei L, Wang F, Li FB, Kinetics and mechanism of propachlor reductive transformation through nucleophilic substitution by dithionite. Chemosphere, 2011, 85, 1438-1443. [28]刘承帅, 韦志琦, 李芳柏, 董军, 游离态Fe(II)驱动赤铁矿晶相重组的Fe原子交换机制:稳定Fe同位素示踪研究. 中国科学: 地球科学, 2016, 46, 1542-1553. 
[29]刘亚楠,陈曼佳,童辉,李芳柏,刘承帅*,华健,龙胜桥,高庭,刘宇晖,夏亚飞. 亚铁驱动针铁矿晶相重组耦合砷氧化机制. 矿物学报, 2018, 39(5), 572-579. 
[30]高原雪; 张玉娇; 陈柏迪; 刘传平; 陈迪云; 刘承帅*. 基于矿物晶体结构的场地重金属污染土壤结构化固定处置. 生态环境学报, 22 (2013) 1058-1062.