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姓名 刘承帅 性别:
职称 研究员 学历 博士研究生
电话 传真:
Email: liuchengshuai@vip.gyig.ac.cn 邮编: 550081
地址 贵阳市观山湖区林城西路99号
简历:

教育经历:
2002/09-2007/07,中科院广州地球化学研究所,环境科学,理学博士;
1997/09-2001/07,武汉大学,环境工程,工学学士。
工作经历:
2015/01 - 至今,中国科学院地球化学研究所,环境地球化学国家重点实验室研究员;
2012/12-2014/12,广东省生态环境与土壤研究所,土壤污染控制与修复中心,主任、研究员;
2014/06-2014/10,香港大学,土木与环境工程系,博士后研究员;
2013/02-2014/02,The University of Iowa,土木与环境工程系,访问学者;
2011/05-2012/12,香港大学,土木与环境工程系,博士后;
2008/03-2008/10,香港理工大学,土木工程系,研究助理;
2007/07-2012/12,广东省生态环境与土壤研究所,助理研究员、副研究员。

 
研究方向:

1. 基于土壤矿物活性的污染物环境地球化学过程。
  主要兴趣集中于矿物-污染物相互作用的生物地球化学机制,包括:①矿物-污染物相互作用的电子传递、矿物晶体结构重组等微观过程; ②土壤矿物-微生物相互作用及其环境效应;③影响典型土壤矿物环境活性的矿物表面与结构性质研究;④矿物-污染物作用过程的金属稳定同位素示踪研究及分馏效应。
2. 土壤重金属污染控制与修复。
   ①基于土壤环境地球化学过程调控的污染重金属稳定/固化脱毒;②重金属稳定/固化的粘土矿物和生物炭等土壤友好材料研究与应用;③工业场地重金属污染土壤异位结构化固定处置技术与设备。

 
承担科研项目情况:

(1)中科院地球化学研究所领域前沿项目,“土壤矿物与重金属相互作用的地球化学机制”,2015.1-2018.12;(在研)
(2)广东省自然科学基金团队项目分专题,“基于铁循环的土壤有机氯还原脱氯过程与原位修复技术”(S2011030002882),2012.1-2015.12;(在研)
(3)广东省杰出青年基金项目,“基于土壤活性矿物的污染物转化脱毒机制”(S2013050014266)2013.10-2017.10;(在研)
(4)广州市国际合作项目,“重金属污染工业场地土壤修复处置与资源化利用关键技术研究与应用示范”(2013C1-E215),2013.1-2014.12。(已结题)
(5)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;(已结题)
(6)国家自然科学基金青年基金项目,“土壤铝氧化物界面酰胺类农药的多相水解转化机制” (40801086),2009.1-2011.12,20万元;(已结题)
(7)International Foundation for Science (IFS),“Hydrolysis of Ester Pesticides in the interface of maize rhizosphere soils in south China” (AC/19668),2009.1-2011.12;(已结题)
(8)广东省科学院优秀青年科技人才基金,“华南红壤界面典型农药转化过程与污染修复技术”(粤科优[2008]03),2008.10-,2011.10;(已会审验收:优秀)
(9)广州市科技计划项目,“基于微生物燃料电池的污泥产电技术”(2008Z1-D331),2008.10-2011.10;(已会审验收)
(10)土壤与农业可持续发展国家重点实验室开放基金,“玉米根际土壤有机成分对界面酰胺类农药水解的影响机制”(08112000042),2009.1-2011.12;(已结题)
(11)广东省科技计划重点项目,“搬迁钢铁企业污染场地土壤健康风险评价与修复处置关键技术集成”(2012A030700011), 2012.7-2014.12,35万元;(已结题)
(12)广东省科技计划项目,“有机氯农药污染土壤高效修复技术与示范”(2011B030900005),2012.1-2014.12;(已结题)

 
专家类别:
职务:
环境地球化学国家重点实验室副主任
社会任职:

中国矿物岩石地球化学学会终身会员;
广东省生态环境与土壤研究所学术会员会委员;
广东省青年科学家协会常务理事

 
获奖及荣誉:

2015年,国家高层次青年拔尖人才

2015年,广州市科学技术一等奖;

2013年,广东省杰出青年基金获得者;

2012年,第三届中国土壤学会优秀青年学者奖;

2008年,广东省科学院优秀青年科技人才;

2007年,中国科学院大学(原中科院研究生院)优秀毕业生;

2005年,广东省科学技术一等奖;

2005年,中国科学院大学刘永龄奖学金特别奖。

 
代表论著:

[1] Hua J, Fei YH, Feng CH, Liu CS*, Liang S, Wang SL, Wu F, Anoxic Oxidation of As(III) during Fe(II)-Induced Goethite Recrystallization: Evidence and Importance of Fe(IV) Intermediate. Journal of Hazardous Materials, 2021, 421, 126806.

[2] Wu F, Hua J, Zhou JM, Liu YH, Long S, Fei YH*, Liu CS*, Facet-specific reactivity of hematite nanocrystals during Fe(II)-catalyzed recrystallization. Chemical Geology, 2021, 583, 120460.

[3] Long SQ, Tong H, Zhang XX, Jia SY, Chen MJ, Liu CS*, Heavy metal tolerance genes associated with contaminated sediments from an E-waste recycling river in Southern China. Frontiers in Microbiology, 2021, 12, 665090.

[4] Gao T, Liu YH, Xia YF, Zhu JM, Wang ZR, Qi M, Liu YZ, Ning ZP, Wu QQ, Xu WP, Liu CS*, Cadmium isotope compositions of Fe-Mn nodules and surrounding soils: Implications for tracing Cd sources. Fundamental Research, 2021, DOI: 10.1016/j.fmre.2021.04.002.

[5] Xu S, Sayer EJ, Eisenhauer N, Lu XK, Wang JJ, Liu CS*, Aboveground litter inputs determine carbon 1 storage across soil profiles: a meta-analysis. Plant and Soil, 2021, 462, 429-444.

[6] Tong H, Zheng CJ, Li B, Swanner ED, Liu CS*, Chen MJ, Xia YF, Liu YH, Ning ZP, Li FB, Feng XB, Microaerophilic Oxidation of Fe(II) Coupled with Simultaneous Carbon Fixation and As(III) Oxidation and Sequestration in Karstic Paddy Soil. Environmental Science & Technology, 2021, 55, 3634-3644.

[7] 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, 2021, 559, 119901.

[8] 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.

[9] 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.

[10] 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.

[11] 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.

[12] 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.

[13] 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.

[14] 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.

[15] 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.

[16] 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.

[17] 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.

[18] 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.

[19] 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.

[20] 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.

[21] 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.

[22] 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.

[23] 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.

[24] 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.

[25] 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.

[26] 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.

[27] 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.