更新日期:2024年10月12日
个人简介
刘承帅,男,1978年7月出生,湖南郴州人。华南农业大学,资源环境学院,教授,博导。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。主要研究方向包括:元素环境地球化学、表层地球系统重金属环境行为及效应、土壤污染控制与修复。入选2014年国家“万人计划”青年拔尖人才、2015年中科院“百人计划”、2016年“广东特支计划”科技创新领军人才、2021年贵州省高层次创新型人才(十层次)、2022年贵州省核心省管专家等。2001年于武汉大学环境科学与工程系获学士学位;2007年于中科院广州地球化学研究所获环境科学博士学位;2007年7月至2014年12月在广东省生态环境与土壤研究所担任助研、副研、研究员;2015年1月至2024年5月,任中科院地球化学研究所环境地球化学国家重点实验室研究员、副主任。其中2008年3月至10月香港理工大学研究助理,2010.5-2011.12香港大学博士后,2013.2-2014.2美国爱荷华大学访问学者。兼任中国土壤学会理事、中国植物营养与肥料学会理事、中国化学会理事、中国矿物岩石地球化学学会环境地质地球化学专业委员会主任等。曾获2020年贵州省首届优秀科技个人奖、2020年中国产学研合作创新奖、2019年国家科技进步二等奖(第9)、2016年广东省科学技术一等奖(第6)、2015第21届全国发明展览会金奖(第1)、2012年第7届国际发明展览会银奖(第3)、2012年“第三届中国土壤学会优秀青年学者奖”、2005年度广东省科学技术一等奖(第14)等。主持包括国家重点研发计划项目、国家自然科学基金重点、联合重点等在内的项目30多项。发表研究论文200多篇,其中SCI收录170多篇(第一/通讯70多篇),截止2023年9月,发表的SCI论文他引7000多次,高引指数43;申请专利53件(发明专利43件),已授权27件(发明专利授权17件,含美国2件、日本1件)。
工作经历
2024.6-至今,华南农业大学,资源环境学院,院长;
2015.1-2024.5,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,副主任、研究员;
2012.12-2014.12, 广东省生态环境与土壤研究所,污染控制与修复研究中心,研究员,中心主任;
2014.06-2014.10,香港大学,博士后研究员(Postdoctoral Research Fellow);
2013. 02-2014.02,美国爱荷华大学环境工程系, 访问学者;
2010.05-2011.12,香港大学,博士后 (Post-doctoral);
2009.01-2012.12,广东省生态环境与土壤研究所,副研究员;
2008.03-2008.10,香港理工大学,研究助理 (Research Assistant);
2007.07-2008.12,广东省生态环境与土壤研究所,助理研究员。
教育经历
1997年-2001年,武汉大学,环境科学与工程系,本科/环境工程,工学学士;
2002年-2007年,中科院广州地球化学研究所,博士研究生(硕博连读)/环境科学,理学博士。
获奖、荣誉称号
国家杰出青年科学基金“元素地球化学”获得者
国家重点研发计划 “场地土壤阳离子态重金属活性钝化新型功能材料研发”首席科学家;
2014年获中组部“万人计划”青年拔尖人才称号
2015年获中科院“百人计划”称号;
2019年被评为贵州省省管专家;
2021年贵州省十层次人才;
2020年获第一届贵州省优秀科技个人奖;
2019年获国家科技进步奖“稻田镉砷污染阻控关键技术与应用”二等奖(排名第9);
2020年获中国产学研合作创新与促进奖产学研合作创新奖个人奖;
2017年获大北农科技奖“镉砷污染稻田安全利用关键技术及产业化”(排名第6);
2016年获广东省科学技术一等奖“红壤区农田镉砷污染阻控关键技术”(排名第6)
2015年获广州市科学技术一等奖:“红壤区农田镉/砷污染控制关键技术与新产品创制”(排名第5)
2015年获“第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》;(排名第1)
2012年获“第三届中国土壤学会优秀青年学者奖”(全国两年一届,一届奖励10名);
2012年获“第7届国际发明展览会银奖”《一类促进土壤中多卤代有机物脱卤解毒的铁锰配合物》;(排名第3)
2010-2011年度获中国科学院广州分院、广东省科学院“优秀青年科技工作者”。
社会、学会及学术兼职
中国土壤学会,理事;
中国植物营养与肥料学会,理事;
中国土壤学会土壤环境专业委员会,委员;
中国土壤学会土壤化学专业委员会,委员;
中国微生物学会地质微生物专业委员会,委员;
广东省土壤学会,常务理事;
广东省土壤学会土壤环境工作委员会,主任;
广东省环境科学学会农业环境保护专业委员会,副主任;
中国科学院污染生态与环境工程重点实验室学术委员会,委员;
土壤多尺度界面过程与调控重庆市重点实验室学术委员会,委员。
研究领域
区域-土壤-植物金属元素迁移转化过程、金属稳定同位素环境地球化学、土壤矿物结构活性及其金属元素环境效应、土壤重金属污染成因与控制
科研项目
[1] 国家自然科学基金杰出青年基金项目,“元素环境地球化学”(42025705),2021.1-2025.12,400万元;
[2] 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),2020.11-2023.12,1409万元;
[3] 国家自然科学基金重点项目,“碳酸盐岩地质高背景区土壤隔形态演化过程及其关键影响因素”(42330712),2024.1-2028.12,233万元;
[4] 中国科学院“西部之光”交叉团队项目-重点实验室合作研究专项,“喀斯特关键带重金属循环与环境效应”,2020.1-2023.12,200万元。
[5] 中国科学院前沿科学重点项目,“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),2017.5-2019.12, 100万元;
[6] 国家自然科学基金-广东省联合基金重点项目,“南岭矿区土壤重金属结构分异特征与污染来源解析” (U1701241), 2018.1-2021.12,283万元;
[7] 国家重点研发计划课题,“金属氧化物与重(类)金属间的氧化还原固定于去除技术研发”(2017YFD0801002),2017.7-2020.12,375万元;
[8] 广东省应用型科技研发资金重大项目,“工业场地污染土壤资源化处置技术研发与成果转化”,(2016B020242006),2016.1-2018.12,800万元;
[9] 广东省特支计划“科技创新领军人才”项目,“土壤矿物相变及其环境效应,2017.1-2019.12, 80万元;
[10] 国家自然科学基金面上项目,“Fe(II)催化铁(氢)氧化物矿物相重组耦合重金属环境行为机制研究”(41673135),2017.1-2020.12,71万元;
[11] 农业部公益性行业科研专项经费项目,“有机化学品污染农田和农产品质量安全综合防治技术方案”(201503107-4),2015.1-2019.12,209万元;
[12] 广东省科学院创新驱动发展能力建设专项资金项目,“游离态Fe(II)-氧化铁相互作用及其重金属钝化效应”,2017.1-2018.12,150万元;
[13] 中国科学院“百人计划”项目,“基于土壤氧化铁地球化学过程的重金属环境行为研究”,2015.1-2018.12,150万元;
[14] 中国科学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”,2015.1-2018.12,70万元;
[15] 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),2011.7-2015.12,200万元(本专题40万元);
[16] 广东省现代农业共性技术创新团队项目(专题专家),“农业面源污染防控与产地环境安全共性技术创新团队”,2017.1-2020.12,100万元(本专题20万元);
[17] 广州市科技计划项目产学研协同创新重大专项,“工业搬迁遗留场地污染土壤资源化处置技术研发与应用”(201704020200),2017.5-2020.4,100万元。
[18] 中组部“万人计划”青年拔尖人才项目,“土壤污染修复”,2015.1-2017.12,150万元;
[19] 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),2012.1-2015.12,65万元;
[20] 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),2013.10-2017.10,100万元;
[21] 广东省科学院科研平台环境与能力建设项目,“污染场地修复技术产业化国家级平台培育”(2016GDASPT-0212),2016.1-2017.12,290万元;
[22] 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), 2012.1-2014.12,35万元;
[23] 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),2011.7-2013.6,10万元;
[24] 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),2013.1-2015.06,35万元。
[25] 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;
[26] International Foundation for Science (IFS),“Hydrolysis of Ester Pesticides in the interface of maize rhizosphere soils in south China” (AC/19668),2009.1-2011.12,1.12万美元;
[27] 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),2008.10-2011.10,25万元;
[28] 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),2008.10-2011.10,15万元;
[29] 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),2009.1-2011.12,5万元。
[30] 广州市住房保障办公室委托项目,“南方钢厂保障性住房(一期)项目重金属超标土壤处置”,2012.3-2012.12, 35万元。
[31] 东莞市环保局委托项目,“东莞市某电镀厂搬迁场地重金属污染土壤处置”,2014.1-2014.12,75万元。
发表论文
已发表的SCI论文(*通讯作者):
第一作者及通讯作者:
[1] Li C, Ran YY, Wu P, Liu P, Yang BY, Gu XY, Zhao P, Liu SR, Song L, Liu YZ, Ning ZP, Sun J*, Liu CS*, Antimony and arsenic migration in a heterogeneous subsurface at an abandoned antimony smelter under rainfall. Journal of Hazardous Materials, 2024, 470, 123156.
[2] Fu YC, Gao T*, Wu QQ, Qi M, Wang ZR, Liu CS*, Mechanism of zinc stress on magnesium deficiency in rice plants (Oryza sativa L.): Insights from magnesium isotopes. Science of The Total Environment, 2024, 923, 171463.
[3] Jin YL, Gao T, Zhao B, Liu YZ, Liu CS*, Qin MH, Modeling spatial trends and exchange fluxes of contaminants in agricultural soil under pollution prevention measures. Journal of Environmental Management, 2024, 354, 120419.
[4] Hu SJ, Liu CS*, Bu HL, Chen MJ, Tang J, Jiang B, Ran Y, Reduced sulfur compounds and carboxylic acid groups in dissolved PFRs of iron‑biochar enhance Cr(VI) reduction in anaerobic conditions. Biochar, 2024, DOI:10.1007/s42773-024-00305-6.
[5] Chen JH*, Wang X, Guo JH, Lv YW, Chen MJ, Tong H, Liu CS*, Heavy Metal-Induced Assembly of DNA Network Biosensor from Double-Loop Hairpin Probes for Ultrasensitive Detection of UO22+ in Water and Soil Samples. Analytical Chemistry, 2024, DOI: 10.1021/acs.analchem.3c05526.
[6] Meng FY, Tong H, Feng CH, Huang ZY, Wu P, Zhou JM, Hua J, Wu F*, Liu CS*, Structural Fe(II)-induced generation of reactive oxygen species on magnetite surface for aqueous As(III) oxidation during oxygen activation. Water Research, 2024, 252, 121232.
[7] Xia YF, Liu YH, Chen T, Xu YD, Qi M, Sun GY, Wu X, Chen MJ, Xu WP, Liu CS*, Combining Cd and Pb isotope analyses for heavy metal source apportionment in facility agricultural soils around typical urban and industrial areas. Journal of Hazardous Materials, 2024, 466, 133568.
[8] Chen JH, Wang X, Lv YW, Chen MJ, Tong H, Liu CS*, Intelligent monitoring of the available lead (Pb) and cadmium (Cd) in soil samples based on half adder and half subtractor molecular logic gates. Talanta, 2024, 271, 125681.
[9] Xia YF, Liu YH, Liu CS*, Gao T, Yin RS, Qi M, Wu HC, Lake sediment archive reveals a distinct response to anthropogenic Pb and Zn deposition with historical periods: Pb-Zn isotope evidence, Environmental Science & Technology, 2023, 57, 15184-15192.
[10] Gao T, Qi M, Wang ZR, Yin RS, Liu CS*, Liu YH, Ke S, Zhao ZQ, Magnesium Isotope Variations in Granite Regoliths From Two Contrasting Climates. Journal of Geophysical Research: Earth Surface, 2023, DOI: 10.1029/2023JF007217
[11] Liu YZ, Liu CS*, Song CS, Chen ZJ, Guan HY, Xing D, Gao T, Sun J, Ning ZP, Xiao TF, Geochemical factors controlling the mobilization of geogenic cadmium in soils developed on carbonate bedrocks in Southwest China. Geoderma, 2023, 437, 116606.
[12] Tong H, Li JH, Chen MJ, Fang YJ, Yi X, Dong LH, Jiang Q, Liu CS*, Iron oxidation coupled with nitrate reduction affects the acetate-assimilating microbial community structure elucidated by stable isotope probing in flooded paddy soil. Soil Biology & Biochemistry, 2023, 183, 109059.
[13] Chen JH, Chen MJ, Tong H, Wu F, Liu YZ, Liu CS*, Fluorescence biosensor for ultrasensitive detection of the available lead based on target biorecognition-induced DNA cyclic assembly. Science of the Total Environment, 2023, 905, 167253.
[14] Hu SJ, Liu CS*, Bu HL, Chen MJ, Fei YH*, Wei YF, Efficient reduction and adsorption of Cr(VI) using FeCl3-modified biochar: roles of persistent free radicals and Fe(II). Journal of Environmental Sciences, 2023, 137, 626-638.
[15] Hua J, Sun J*, Chen MJ, Liu CS*, Wu F, Aqueous Fe(II)‑catalyzed iron oxide recrystallization: Fe redox cycling and atom exchange, mineralogical recrystallization and contributing factor. Reviews in Environmental Science and Biotechnology, 2023, DOI: 10.1007/s11157-023-09646-3.
[16] Meng FY, Bu HL, Fei YH*, Chen MJ, Lei QK, Liu D, Hua J, Wu F, Liu CS*, Effects of clay minerals on Fe2+-induced phase transformation of ferrihydrite. Applied Geochemistry, 2022, 144, 105401.
[17] Liu YZ, Xiao TF*, Zhu JM, Gao T, Xiong Y, Zhu ZJ, Ning ZP, Liu CS*, Redistribution and isotope fractionation of endogenous Cd in soil profiles with geogenic Cd enrichment. Science of The Total Environment, 2022,
[18] Hua J, Feng CH, Sun J, Wu F, Wu F*, Liu CS*, Facet-preferential reduction of hematite nanocrystals by Shewanella oneidensis MR-1: An iron isotope tracer study. Chemical Geology, 2022, 614, 121166.
[19] Qi M, Gao T*, Wang ZR, Liu YH, Xia YF, Song CS, Liu YZ, Liu CS*, Iron solid-phase differentiation controls isotopic fractionation during lateritic weathering of basalt. Catena, 2022, 217, 106512.
[20] Song RM, Li ZM, Li WL, An Y, Li M, Qin HL*, Liu CS*, Improved adsorption and desorption behavior of Cd on thiol‑modified bentonite grafted with cysteamine hydrochloride. Research on Chemical Intermediates, 2022, DOI: 10.1007/s11164-022-04711-y.
[21] Liu YH, Xia YF, Wang ZR, Gao T*, Zhu JM, Qi M, Sun J, Liu CS*, Lithologic controls on the mobility of Cd in mining-impacted watersheds revealed by stable Cd isotopes. Water Research, 2022, 220, 118619.
[22] Gao T, Wu QQ, Xia YF, Liu YH, Zhu JM, Qi M, Song CS, Liu YZ, Sun GY, Liu CS*, Flooding-drainage alternations impact mobilization and isotope fractionation of cadmium in soil-rice systems. Journal of Hazardous Materials, 2022, 436, 129048.
[23] Zhou JM, Liu YZ, Bu HL, Liu P, Sun J, Wu F, Hua J, Liu CS*, Effects of Fe (II)-induced transformation of scorodite on arsenic solubility. Journal of Hazardous Materials, 2022, 429, 128274.
[24] Liu YZ, Chen ZJ, Xiao TF, Jia SY*, Sun J, Gao T, Liu CS*, Enrichment and environmental availability of cadmium in agricultural soils developed on Cd-rich black shale in southwestern China. Environmental Science and Pollution Research, 2022, 29, 36243-36254.
[25] 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, 2022, 421, 126806.
[26] 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.
[27] 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.
[28] 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, 1, 269-276.
[29] 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. (IF=3.299, 1区)
[30] 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. (IF=7.864, 1区)
[31] 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. (IF=3.362)
[32] Tong H, Chen MJ, Lv YH, Liu CS*, Zheng CJ, Xia YF, Changes in the microbial community during microbial microaerophilic Fe(II) oxidation at circumneutral pH enriched from paddy soil. Environmental Geochemistry and Health. 2021, 43, 1305-1317. (IF=3.472)
[33] Xie SW, Wu F, Ning ZP, Chen MJ, Liu CS*, Huang Q, Meng FY, Liu YH, Zhou JM, Xia YF, Two-step calculation method to enable the ecological and human health risk assessment of remediated soil treated through thermal curing. Soil Ecology Letters, 2021, 3, 266-278.
[34] Chen MJ#, Tong H#, Qiao JT, Lv YH, Jiang Q, Gao YX, Liu CS*, Microbial community response to the toxic effect of pentachlorophenol in paddy soil amended with an electron donor and shuttle. Ecotoxicology and Environmental Safety, 2020, 205, 111328. (IF=4.872)
[35] 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. (IF=6.792, 1区)
[36] Ding W, Tong H, Zhao D, Zheng HL, Liu CS*, Li JJ, Wu F*, A novel removal strategy for copper and arsenic by photooxidation coupled with coprecipitation: Performance and mechanism. Chemical Engineering Journal, 2020, 401, 126102. (IF=10.652, 1区)
[37] 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. (IF=7.864, 1区)
[38] 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. (IF=6.551, 1区)
[39] 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. (IF=4.659, 1区)
[40] Fei YH, Zhao D, Liu Y, Zhang WH, Tang YY, Huang XX, Wu QH, Wang YX, Xiao TF*, Liu CS*, Feasibility of sewage sludge derived-hydrochars for agricultural application: Nutrients and heavy metals. Chemosphere, 2019, 236, 124841. (IF=5.778, 2区)
[41] 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. (IF=3.362, 2区)
[42] 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 (IF=1.507)
[43] 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. (IF=7.577, 1区)
[44] 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. (IF=3.418)
[45] 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. (IF=2.311, 2区)
[46] Fei YH, Chen YX, Liu CS*, Xiao TF, Biochar Addition Enhances Phenanthrene Fixation in Sediment. Bulletin of Environmental Contamination and Toxicology, 2019, 103, 163-168. (IF=1.657, 4区)
[47] 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. (IF=9.130, 1区)
[48] 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. (IF=4.659, 1区)
[49] 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. (IF=7.632, 2区)
[50] 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. (IF=3.742, 1区)
[51] 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. (IF=6.792, 2区)
[52] 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, (IF=2.285, 3区)
[53] Fei YH, Hua J, Liu CS*, Li FB, Zhu ZK, Xiao TF, Chen MJ, Gao T, Wei ZQ, Hao LK, Aqueous Fe(II)-Induced Phase Transformation of Ferrihydrite Coupled Adsorption/Immobilization of Rare Earth Elements. Minerals, 2018, 8, 357. (IF=2.380, 3区)
[54] Hua J, Chen MJ, Liu CS*, Li FB, Long J, Gao T, Wu F, Lei J, Gu MH, Cr Release from Cr-substituted Goethite During Aqueous Fe(II)-Induced Recrystallization. Minerals, 2018, 8, 367. (IF=2.380, 3区)
[55] 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. (IF=2.805, 3区)
[56] 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 (IF=9.038, 1区)
[57] Fei YH, Liu CS*, Li FB, Chen MJ, Tong H, Liu CP, Liao CZ, Combined modification of clay with sulfhydryl and iron: Toxicity alleviation in Cr-contaminated soils for mustard (Brassica juncea) growth. Journal of Geochemical Exploration, 2017, 176, 2-8 (IF=3.352, 3区)
[58] 刘承帅, 李芳柏, 陈曼佳, 廖长忠, 童辉, 华健, Fe(II)催化水铁矿晶相转变过程中Pb的吸附与固定(Adsorption and Stabilization of Lead during Fe(II)-catalyzed Phase Transformation of Ferrihydrite). 化学学报 (Acta Chimica Sinica), 2017, 75, 621-628. (IF=2.759, 3区)
[59] 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. (IF=3.362, 2区)
[60] 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. (IF=9.038, 1区)
[61] Chen MJ, Liu CS*, Chen PC, Tong H, Li FB*, Qiao JT, Lan Q, Dynamics of the microbial community and Fe(III)-reducing and dechlorinating microorganisms in response to pentachlorophenol transformation in paddy soil. Journal of Hazardous Materials, 2016, 312, 97-105. (IF=9.038, 1区)
[62] Lan Q, Cao MY, Ye ZJ, Zhu JS, Chen MJ, Chen XQ, Liu CS*, Effect of oxalate and pH on photodegradation of pentachlorophenol in heterogeneous irradiated maghemite System. Journal of Photochemistry & Photobiology A: Chemistry, 2016, 328, 198-206. (IF=3.306, 3区)
[63] Chen MJ, Tong H, Liu CS*, Chen DD, Li FB*, Qiao JT, A humic substance analogue AQDS stimulates Geobacter sp. abundance and enhances pentachlorophenol transformation in a paddy soil. Chemosphere, 2016, 160, 141-148. (IF=5.778, 2区)
[64] 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. (IF=5.795, 1区)
[65] 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 (IF=4.333, 2区)
[66] Liu CS, Wang YK, Li FB*, Chen MJ, Zhai GS., Tao L, Liu CP, Influence of geochemical properties and land-use types on the microbial reduction of Fe(III) in subtropical soils. Environmental Science: Processes & Impacts, 16 (2014) 1938-1947. (IF=3.238, 3区)
[67] 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. (IF=4.192, 1区)
[68] 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. (IF=4.192, 1区)
[69] Liu CS, Shih K*, Sun CX, Wang F, Oxidative degradation of propachlor by ferrous and copper ion activated persulfate. Science of the Total Environment, 2012, 416, 507-512. (IF=6.551, 2区)
[70] 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. (IF=10.652, 2区)
[71] Li FB*, Liu CS*, Zhang LJ, et al., The oxidative degradation of 2-mercaptobenzothiazole at the interface of β-MnO2 and water. Journal of Hazardous Materials, 2008, 154, 1098-1105. (IF=9.038, 1区)
[72] Liu CS, Li FB*, Li XM, et al., The Effect of Iron Oxides and Oxalate on the Photodegradation of 2-Mercaptobenzothiazole. Journal of Molecular Catalysis A: Chemistry, 2006, 252, 40-48. (IF= 3.687, 2区)
[73] 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. (IF=5.778, 2区)
[74] Liu CS, Wang F, Higgins CP, Shih K*, Effect of temperature on oxidative transformation of perfluorooctanoic acid (PFOA) by persulfate activation in water. Separation and Purification Technology, 91 (2012) 46-51. (IF=5.774, 2区)
[75] Liu CS, Shih K*, Wang F, Oxidative decomposition of perfluorooctanesulfonate in water by permanganate. Separation and Purification Technology, 87 (2012) 95-100. (IF=5.774, 2区)
[76] Liu CS, Zhang LJ, Feng CH, Wu CA, Li FB*, Li XZ, Relationship between oxidative degradation of 2-mercaptobenzothiazole and physicochemical properties of manganese (hydro)oxides. Environmental Chemistry, 6 (2009) 83-92. (IF=1.910, 3区)
[77] Dong J, Li YT, Zhang LJ, Liu CS*, Zhuang Li, Sun LN, Zhou JM, The oxidative degradation of sulfadiazine at the interface of α-MnO2 and water. Journal of Chemical Technology & Biotechnology, 84 (2009) 1848-1853. (IF=2.750, 2区)
[78] Liu CS, Zhang LJ, Li FB*, Wang Y, Gao Y, Li XZ, Cao WD, Feng CH, Dong J, Sun LN, Dependence of Sulfadiazine Oxidative Degradation on Physicochemical Properties of Manganese Dioxides. Industrial & Engineering Chemistry Research, 48 (2009) 10408-10413. (IF=3.573, 2区)
[79] Liu CS, Shih K*, Gao YX, Li FB*, Wei L, Dechlorinating transformation of propachlor through nucleophilic substitution by dithionite on the surface of alumina. Journal of Soils and Sediments, 12 (2012) 724-733. (IF=2.763, 3区)
[80] Liu CS, Wang XQ, Li XJ, Cao WD*, Yang JY, Detoxification of Arsenite through Adsorption and Oxidative Transformation on Pyrolusite. CLEAN-Soil Air Water, 40 (2012) 1265-1272. (IF=1.603, 4区)
[81] Wei L, Li FB, Liu CS*, Liu CP, Chen MJ, Lan Q, Heterogeneous Nucleophilic Transformation of Metolachlor by Bisulfide on Alumina Surface. CLEAN-Soil Air Water, 41 (2013) 856-864. (IF=1.603, 4区)
[82] Liu CS, Gao YX, Li FB*, et al., Photodegradation of 2-Mercaptobenzothiazole in the iron oxide/oxalic acid/UVA system. Chinese Journal of Catalysis, 27 (2006) 139-145. (IF=6.146, 2区)
[83] Dong J, Zhang LJ, Liu H, Liu CS*, Gao YX, Sun LN, The oxidative degradation of 2-mercaptobenzothialzole by different manganese dioxides. Fresenius Environmental Bulletin, 19 (2010) 1615-1622. (IF=0.553, 4区)
[84] Chang CY, Li FB, Liu CS*, Gao JF, Tong H, Chen MJ, Fractionation characteristics of rare earth elements (REEs) linked with secondary Fe, Mn, and Al minerals in soils. Acta Geochmica, 2016, 35, 329-339. (EI收录)
[85] Xu S, Geng WX, Sayer EJ, Zhou GY, Zhou P, Liu CS*, Soil microbial biomass and community responses to experimental precipitation change: A meta-analysis. Soil Ecology Letters, 2020, 2, 93-109.
第二作者:
[86] Xie SW, Liu CS, He B, Chen MJ*, Gao T, Wei XH, Liu YH, Xia YF, Sun QY, Geochemical Fractionation and Source Identification of Pb and Cd in Riparian Soils and River Sediments from Three Lower Reaches Located in the Pearl River Delta. International Journal of Environmental Research and Public Health, 2022, 19, 13819.
[87] Xu WP, Liu CS, Zhu JM, Bu HL*, Tong H, Chen MJ*, Tan DC, Gao T, Liu YZ, Adsorption of cadmium on clay-organic associations in different pH solutions: The effect of amphoteric organic matter. Ecotoxicology and Environmental Safety, 2022, 236, 113509.
[88] Wu QQ, Liu CS, Wang ZR, Gao T*, Liu YH, Xia YF, Yin RS, Qi M, Zinc regulation of iron uptake and translocation in rice (Oryza sativa L.): Implication from stable iron isotopes and transporter genes. Environmental Pollution, 2022, 297, 118818.
[89] Wu SS, Liu CS, Li XG, Xiao BH*, Hu QY, Freeze-thaw controlled aggregation mechanism of humic acid-coated goethite: Implications for organic carbon preservation. Geoderma, 2022, 406, 115514.
[90] Liao CZ, Liu CS, Su MH, Shih K*, Quantification of the Partitioning Ratio of Minor Actinide Surrogates between Zirconolite and Glass in Glass-Ceramic for Nuclear Waste Disposal. Inorganic Chemistry, 2017, 56, 9913-9921. (Nature Index期刊,IF=4.825)
[91] Liao CZ, Liu CS, Lee PH, Stennett, MC, Hyatt NC*, Shih K*, Combined Quantitative X-ray Diffraction, Scanning Electron Microscopy, and Transmission Electron Microscopy Investigations of Crystal Evolution in CaO-Al2O3-SiO2-TiO2-ZrO2-Nd2O3-Na2O System. Crystal Growth & Design, 2017, 13, 1079-1087. (IF=4.089)
[92] Chen MJ, Liu CS, Li XM, Huang WL, Li FB, Iron reduction coupled to reductive dechlorination in red soil: A review. Soil Science, 179 (2015) 457-467. (IF=1.122)
[93] Tong H, Liu CS, Li FB, Luo CL, Chen MJ, Hu M, The key microorganisms for anaerobic degradation of pentachlorophenol in paddy soil as revealed by stable isotope probing. Journal of Hazardous Materials, 298 (2015) 252-260. (IF=9.038)
[94] Tang Y, Liu, CS, Shih K, Beneficial metal stabilization mechanisms using simulated sludge incineration ash for ceramic products. Journal of Chemical Technology & Biotechnology, 89 (2013) 536-543. (IF=2.750)
[95] Zhang LX, Liu CS, Zhuang Li, Li WS, Zhou SG, Zhang JT, Manganese dioxide as alternative cathodic catalyst to platinum in microbial fuel cells. Biosensors and Bioelectronics, 24 (2009) 2825-2829. (IF=10.257)
[96] Wang Y, Liu CS, Li FB, Liu CP, Liang JB, Photodegradation of polycyclic aromatic hydrocarbon pyrene by iron oxide in solid phase. Journal of Hazardous Materials, 162 (2009) 716-723. (IF=9.038)
[97] Li XJ, Liu CS, Li FB, Li YT, Zhang LJ, Liu CP, Zhou YZ, The oxidative transformation of sodium arsenite at the interface of α-MnO2 and water. Journal of Hazardous Materials, 173 (2009) 657-681. (IF=9.038)
[98] Wang F, Liu CS, Shih K, Adsorption behavior of perfluorooctanesulfonate (PFOS) and perfluorooctanoate (PFOA) on boehmite. Chemosphere, 89 (2012) 1009-1014. (IF=5.778)
[99] Liang CH, Liu CS, Li FB, Wu F, The effect of Praseodymium on the adsorption and photocatalytic degradation of azo dye in aqueous Pr3+-TiO2 suspensions. Chemical Engineering Journal, 147 (2009) 219-225. (IF=10.652)
[100] Wang XG, Liu CS, Li FB, et al., Photodegradation of 2-mercaptobenzothiazole in the gamma-Fe2O3/oxalate suspension under UVA light irradiation. Journal of Hazardous Materials, 153 (2008) 426-433. (IF=9.038)
[101] Lei J, Liu CS, Li FB, et al., Photodegradation of orange І in the heterogeneous iron oxide-oxalate complex system under UVA irradiation. Journal of Hazardous Materials, 137 (2006) 1016-1024. (IF=9.038)
第三作者:
[102] Dong LH, Chen MJ, Liu CS, Lv YH, Wang XG, Lei QK, Fang YJ, Tong H*, Microbe interactions drive the formation of floating iron films in circumneutral wetlands. Science of The Total Environment, 2023, 906, 167711.
[103] Jin YL, Xiang YW, Liu CS, Yan LB, Li JX, Li Z&, Zhao B, Qi SQ, Plant secondary succession and soil degradation in humid red beds areas, South China. Ecological Indicators, 2023, 154, 11054.
[104] Zhou R, Li H, Liu CS, Liu YZ, Lee JF, Lin YJ, Yan Z, Xu ZY, Yi XY, Feng CH, Magnetic anaerobic granular sludge for sequestration and immobilization of Pb. Water Research, 2023, 239, 120022.
[105] Fang YJ, Chen MJ, Liu CS, Dong LH, Zhou JM, Yi X*, Ji DQ, Qiao JT, Tong H*, Arsenic release from microbial reduction of scorodite in the presence of electron shuttle in flooded soil. Journal of Environmental Sciences, 2022, 126, 113-122.
[106] Huang ZY, Ma HX, Liu CS, Meng FY, Lee JF, Lin YJ, Yi XY, Dang Z, Feng CH*, A coupled electrochemical process for schwertmannite recovery from acid mine drainage: Important roles of anodic reactive oxygen species and cathodic alkaline. Journal of Hazardous Materials, 2023, 451, 131075.
[107] Bu HL*, Wei YF, Liu CS, Liu D, Tan DY, Liu HM, Effects of illite–smectite clay minerals on the thermal evolution of aliphatic organic matter‑clay complexes: a study with thermogravimetry coupled with Fourier transform infrared spectroscopy (TG‑FTIR). Journal of Thermal Analysis and Calorimetry, 2022, DOI: 10.1007/s10973-022-11829-z.
[108] Fang YJ, Chen MJ, Liu CS, Dong LH, Zhou JM, Yi X*, Ji DQ, Qiao JT, Tong H*, Arsenic release from microbial reduction of scorodite in the presence of electron shuttle in flooded soil. Journal of Environmental Sciences, 2022, 126, 113-122.
[109] Deng YR, Zhang BJ, Liu CS, Li FB, Fang LP, Dang Z, Yang C*, Xiong Y, He CF, Tetracycline-induced release and oxidation of As(III) coupled with concomitant ferrihydrite transformation. Environmental Science & Technology, 2022,
[110] Chen JH, Pan JF, Liu CS, A versatile sensing platform for Cd2+ detection in rice samples and its applications in logic gate computation. Analytical Chemistry, 2020, 92, 6173-6180. (IF=6.785)
[111] Fang LP, Xu L, Liu CS, Li J, Huang LZ, Enhanced reactivity and mechanisms of copper nanoparticles modified green rust for p-nitrophenol reduction. Environment International, 2019, 129, 299-307. (IF=7.577)
[112] Tao L, Li FB*, Liu CS, Feng XH, Gu LL, Wang BR, Wen SL, Xu MG, Mitigation of soil acidification through change in mineralogy of soils in southern China as affected by long-term fertilization. Catena, 2019, 174, 227-234. (IF=4.333)
[113] Tang YY, Shih KM, Liu CS, Liao CZ, Cubic and tetragonal ferrite crystal structures for copper ion immobilization in iron-rich ceramic matrix. RSC Advances, 2016, 6, 28579-28585. (IF=3.119)
[114] Frierdich AJ, Helgeson M, Liu CS, Wang C, Rosso KM, Scherer MM, Iron atom exchange between hematite and aqueous Fe(II). Environmental Science & Technology, 49 (2015) 8479-8486. (IF=7.864)
[115] Liu CP, Yu HY, Liu CS, Li FB, Xu XH, Wang Q, Arsenic availability in rice from a mining area: Is amorphous iron oxide-bound arsenic a source or sink? Environmental Pollution, 199 (2015) 95-101. (IF=6.792)
[116] Lu X, Shih K, Liu CS, Wang F, Extraction of Metallic Lead from Cathode Ray Tube (CRT) Funnel Glass by Thermal Reduction with Metallic Iron. Environmental Science & Technology, 47 (2013) 9972-9978. (IF=7.864)
[117] Lan Q, Li FB, Liu CS, et al., Heterogeneous Photodegradation of Pentachlorophenol with Maghemite and Oxalate under UV Illumination. Environmental Science & Technology, 42 (2008) 7918-7923. (IF=7.864)
[118] Li FB, Wang XG, Liu CS, et al., Reductive transformation of pentachlorophenol on the interface of subtropical soil colloids and water. Geoderma, 148 (2008) 70-78. (IF=4.848)
[119] Liang CH, Li FB, Liu CS, et al., The enhancement of adsorption and photocatalytic activity of rare earth ions doped TiO2 for the degradation of orange I. Dyes and Pigments, 76 (2008) 488-484. (IF=4.613)
[120] Li FB, Chen JJ, Liu CS, et al., Effect of iron oxides and carboxylic acids on photochemical degradation of bisphenol A. Biology and Fertility of Soils, 42 (2006) 409-417. (IF=5.521)
[121] Xie ZY, Chen NC, Liu CS, Zhou JM, Xu SG, Zheng YJ, Li FB, Xu YL, Synthesis and characterization of ethylenediamine tetraacetic acid tetrasodium salt loaded in microcapsules with slow release properties. Chinese Journal of Chemical Engineering, 18 (2010) 149-155. (IF=2.627)
[122] Li FB, Li XZ, Liu CS, et al., Effect of Oxalate on Photodegradation of Bisphenol A at the Interface of Different Iron Oxides. Industrial & Engineering Chemistry Research, 46 (2007) 781-787. (IF=3.573)
[123] Li FB, Li XZ, Liu CS, et al., Effect of alumina on photocatalytic activity of iron oxides for bisphenol A degradation. Journal of Hazardous Materials, 149 (2007) 199-207. (IF=9.038)
[124] Tang YY, Liu CS, Shih KM, Stabilized Nickel and Copper in a Ceramic Matrix and Their Leaching Behavior. Geo-Chicago 2016 , 273 (2016) 79-885. (EI收录)
[125] Lv YH, Wu F, Liu CS, Liao CZ, Fei YH, Chen MH, Hou MF, Preparation and characterization of polyacrylate functionalized polythiophene films. MATEC Web of Conferences, 2018. (EI收录)
出版专著和教材
[1] 徐智敏、刘承帅、尧一骏,建设用地土壤污染风险管控与修复技术,华中科技大学出版社,2022.11.1,257页,42.2万字。
[2] Fei YH, Liu CS*, Chapter 12: Detoxification and resource recovery of chromium-containing wastes (18 pages), in Environmental Materials and Waste: Resource Recovery and Pollution Prevention (760 pages). Elsevier, 2016.
科研创新
[1] Chengshuai Liu, Yahui Lv, Wei Wu, Fei Wu, Fangbai Li, Site heavy metal contaminated soil treatment equipment and treatment method therefor, US Patent, US 11358189B2, 申请日:2019.1.8,授权日:2022.6.14. (授权)
[2] 刘承帅,吕亚辉,吴维,吴非,李芳柏,重金属污染现场土壤处理设备,日本专利号:特许第7044868号. 申请日:2019.1.8,授权日:2022.3.22. (授权)
[3] Chengshuai Liu, Xinwen Lu, Kaimin Shih, Fangbai Li, Method for recovering Lead from Lead-contaminated discarded electronic waste cathode ray tube glass, US Patent, US 9650693B2. 申请日:2012.10.17,授权日:2017.05.16. (授权)
[4] 李芳柏,崔江虎,刘传平,刘承帅。鉄の基の生物の炭材料、その制备技术およびその土壌污染管理中の応用. 日本专利号:特许第6339703号. (授权) 申请日:2014.11.05,授权日:2018.05.18
[5] 夏亚飞,刘承帅,高庭,刘宇晖。一种土壤Cd/Pb复合污染双金属同位素源解析方法及系统,国际申请号:PCT/CN2022/127186. 申请日:2022.10.25. (国际PCT专利)
[6] 刘承帅,李芳柏。基于粘土的重金属热固化剂及其固化重金属的方法,专利号:ZL 201210107104.3。(授权) 申请日:2012.04.12,授权日:2018.01.05
[7] 刘承帅,王萌萌,李芳柏,黄宁生。一种巯基-铁基复合改性粘土及其制备方法,专利号:ZL 201310135109.1。(授权) 申请日:2013.04.17,授权日:2015.03.11
[8] 刘承帅,李芳柏,童辉,刘传平,陈曼佳,于焕云。一种铁基-腐殖质复合材料及其在土壤重金属污染治理中的应用,专利号:ZL 201510390750.9。 (授权) 申请日:2015.07.03,授权日:2017.02.22
[9] 刘承帅,路欣雯,施凯闵,李芳柏。一种从含铅废弃电子垃圾阴极射线管玻璃中回收利用铅的方法,专利号:ZL 201210345035.X。(授权) 申请日:2012.09.17,授权日:2013.02.13
[10] 刘承帅, 廖长忠, 施凯闵, 陶亮, 李芳柏. 一种用于铬渣干法固定解毒的解毒方法, 专利号:ZL 201310655095.6。(授权) 申请日:2013.12.06,授权日:2015.08.19
[11] 刘承帅,廖长忠,施凯闵,唐圆圆,李芳柏,陈曼佳,童辉,于焕云。一种用于铬渣中铬双重固定解毒的玻璃陶瓷化方法,专利号:ZL 201510713666.6. (授权) 申请日:2015.10.27,授权日:2018.06.29
[12] 刘承帅,吕亚辉,杨启豪,黄石光,李芳柏,李乐。一种污染土壤的安全处理利用方法,专利号:ZL2019108116323.0,(授权) 授权日:2020.08.30
[13] 刘承帅,廖长忠,吕亚辉,马胜寿. 一种含铁的钙钛锆石玻璃陶瓷基材及其制备方法. 专利号:ZL202011627095.1 (授权) 申请日:2020.12.30,授权日:
[14] 吴非,刘承帅,李芳柏,陈曼佳,童辉,廖长忠。一种有机污染物-重金属复合污染土壤的修复方法,专利号:ZL 201610988109.X. (授权) 申请日:2016.11.10,授权日:2020.04.21
[15] 李芳柏,陶亮,刘承帅,刘亮。一类促进土壤中多卤代有机物脱卤解毒的铁锰配合物,专利号:ZL 200710028313.8。(授权) 申请日:2007.05.29,授权日:2011.02.09
[16] 陶亮,万开,刘承帅,吴对林,李芳柏,黄奂彦,曾彩明。一种原位修复重金属六价铬污染土壤的方法,专利号:ZL 201410460125.2 (授权) 申请日:2014.09.11,授权日:2017.06.13
[17] 李芳柏,崔江虎,刘传平,刘承帅。一种铁基生物炭材料、其制备工艺以及在土壤污染治理中的应用,专利号:ZL 201410538633.8 (授权) 申请日:2014.10.13,授权日:2017.04.05
[18] 杨国义,郑文棠,郭岩,丁金伟,刘承帅,肖亮洪,李彬。河涌污染底泥处理的构筑物装置,专利号:ZL 201510299042.4 (授权) 申请日:2015.06.03,授权日:2017.07.11
[19] 李芳柏,陈鹏程,童辉,刘承帅,陈曼佳。一株硝酸盐依赖亚铁氧化菌株及其应用,专利号:ZL 201510885137.4.(授权)申请日:2015.12.03,授权日:2018.11.27
[20] 李芳柏,童辉,陈鹏程,刘承帅,陈曼佳。一株能转化重金属的贪铜菌属菌株及其应用,专利号:ZL 201510885689.5. (授权)申请日:2015.12.03,授权日:2016.03.16
[21] 廖长忠,吴非,刘承帅,Kaimin Shih,李芳柏。一种阴极射线管玻璃无害化制备陶瓷的方法,专利号:ZL 201710058226.0. (授权)申请日:2017.01.23 授权日:2021.07.23
[22] 吕亚辉,刘承帅,李芳柏,吴非,陈梦华。一种用于农产品残留农药降解的钛硒复合溶胶及其制备方法和应用,专利号:ZL 201710168247.8.(授权) 申请日:2017.03.21,授权日:2020.08.28
[23] 谢绍文,刘承帅,吴非。一种重金属污染土壤生态风险评估方法,专利号:ZL202011039984.6. (授权) 申请日:2020.09.28,授权日:2022.10.21
[24] 谢绍文,刘承帅,吴非。一种重金属污染土壤人体健康风险评估方法,专利号:ZL202011038942.0. (授权) 申请日:2020.09.28,授权日:2022.10.21
[25] 陈曼佳,刘承帅,乔江涛,童辉,周继梅,吕亚辉。一种生物纳米铁及其制备方法与应用,专利号:ZL202010655783.2. 申请日:2020.7.20,授权日:2022.11.15
[26] 刘承帅,吕亚辉,吴维,吴非,李芳柏。场地重金属污染土壤治理设备及其治理方法,专利号:ZL201810283154.4. (授权)申请日:2018.04.02,授权日:2023:2023.10.07
[27] 刘承帅, 李芳柏, 陶亮。一类促进卤代有机物污染土壤脱卤解毒的羟基酸钛配合物及其制备方法和应用,公开号:201210100684.3. 申请日:2012.04.06
[28] 刘承帅, 吕亚辉, 陈曼佳, 李芳柏。一种用于降解农产品中农药及重金属的硒掺杂纳米钛溶胶及其制备方法和应用,申请号:201710168235.5. 申请日:2017.03.21
[29] 刘承帅,童辉,吕亚辉,雷静,王向琴,陈曼佳,李芳柏,于焕云,方圆。一种用于农产品采后保鲜杀菌的复合环保材料及制备方法与应用,申请号:201910194087.3 申请日:2019.03.14
[30] 刘承帅,吕亚辉,杨启豪,黄石光,李芳柏,李乐. 一种污染土壤的安全处理利用方法. 申请号:201910816323.0 申请日:2019.08.30
[31] 夏亚非, 刘承帅, 高庭, 刘宇晖。一种土壤Cd/Pb复合污染双金属同位素源解析方法及系统,申请号:CN202111265253.8,申请日:2021.10.28.
[32] 刘意章, 刘承帅, 宁增平, 孙静。模拟氧化还原交替变化的简易装置,申请号:CN202111240670.7,申请日:2021.10.25
[33] 陈俊华, 刘承帅, 潘家峰, 邓芳。一种用于检测冠状病毒的分子逻辑门智能化检测系统及其应用,申请号:CN202111362358.5,申请人:2021.11.17
[34] 陈俊华, 刘承帅, 潘家峰, 邓芳。一种抗生素残留检测方法及其检测试剂盒,申请号:CN202111363454.1,申请人:2021.11.17
[35] 童辉,刘承帅,陈曼佳,李芳柏,王琦,刘亚楠。微好氧铁氧化菌团治理砷污染土壤的方法,申请号:201711279584.0. 申请日:2017.12.07
[36] 吴非,刘承帅,高庭,吕亚辉,李芳柏。一种固定化马铃薯多酚氧化酶及其农残降解应用,申请号:201810097041.5. 申请日:2018.01.31
[37] 宁增平,徐浩,刘承帅,付金帅,高庚申,刘意章,孙静。煤矿酸性废水的处理装置、处理系统及处理方法,申请号:202310323891.3. 申请日:2023.3.30.
[38] 宁增平,谢邵文,刘承帅,徐健乐,刘意章,孙静。一种重金属污染土壤修复后建材化再利用的环境风险评估方法. 申请号:202211614007.3. 申请日:2022.12.15.
[39] 杨启豪, 黄石光, 胡松水, 黄志刚, 李乐, 刘承帅。一种污泥脱水剂及其制备方法、脱水方法,申请号:201711362486.3. 申请日:2017.12.18
[40] 黄石光, 吴娟, 吴广丰, 刘承帅, 杨启豪, 胡松水。一种降低农药残留的降解剂,申请号:201811532392.0. 申请日:2018.12.14
[41] 黄石光, 刘承帅, 李乐, 李善军, 黎祖然, 杨启豪, 胡松水, 吴广丰. 一种场地重金属污染土壤资源化处置方法,申请号:201811550392.3 申请日:2018.12.18
[42] 黄石光, 刘承帅, 李乐, 李善军, 黎祖然, 杨启豪, 胡松水, 吴广丰. 一种场地重金属污染土壤资源化低成本处置方法,申请号:201811537129.0 申请日:2018.12.15
[43] 秦好丽,宋瑞明,安娅,刘承帅,李治梅,孙荣国。一种用于镉去除的巯基-铁基复合改性膨润土及其制备方法,申请号:202211405191.0
[44] 黄石光, 吴娟, 李乐, 胡松水, 刘承帅, 吴广丰, 杨启豪. 一种农作物药物残留去除剂. 申请号:201811550379.8 申请日:2018.12.18
[45] 苏敏华, 廖长忠, 刘泽权, 刘承帅, 陈迪云. 一种通过尖晶石的生成稳定废弃物中金属锌的方法. 申请号:201910284406.X. 申请日:2019.04.09
[46] 苏敏华, 刘泽权, 廖长忠, 刘承帅, 陈迪云. 一种通过尖晶石的生成稳定废弃物中金属镍的方法. 申请号:201910284255.8. 申请日:2019.04.09
[47] 苏敏华, 廖长忠, 刘泽权, 刘承帅, 陈迪云. 一种通过尖晶石的生成稳定废弃物中金属铜的方法. 申请号:201910286992.1 申请日:2019.04.09
[48] 陈曼佳,刘承帅,乔江涛,童辉,周继梅,吕亚辉. 一种生物纳米磁铁矿及其制备方法与应用. 申请号:202010655783.2 申请日:2020.07.09
[49] 徐文坡、卜红玲、刘承帅、陈曼佳、龙胜桥、童辉,一种有机改性蒙脱石复合材料及其应用,申请号:202111042600.0
[50] 卜红玲,刘承帅,陈曼佳,徐文坡,胡淑捷,雷琴凯,一种蒙脱石复合材料及其吸附重金属应用,申请号:202111066836.8
[51] 夏亚飞,刘承帅,高庭,刘宇晖,一种土壤Cd/Pb复合污染双金属同位素源解析方法及系统,申请号:202111265253.8,申请日:2021.10.28.
[52] 胡淑捷,刘承帅,卜红玲,陈曼佳,一种含高持久性自由基生物炭的制备及对重金属的去除应用,申请号:202210393781X
指导学生情况
指导博士研究生:
夏亚飞2024年取得中科院大学环境科学博士学位
华健2023年取得武汉大学环境科学博士学位
周继梅2023年取得中科院大学环境科学博士学位
龙胜桥 2022年取得中科院大学环境科学博士学位
吴非2022年取得中科院大学环境科学博士学位
刘宇晖2022年取得中科院大学地球化学博士学位
高庭 2020年取得中科院大学环境科学博士学位
指导硕士研究生:
苟子论 2024年取得中科院大学地球化学硕士学位
雷琴凯 2023年取得广东工业大学环境工程硕士学位
郑春菊2021年取得中科院大学环境科学硕士学位
夏亚飞 2020年取得中科院大学环境工程硕士学位
刘亚楠 2018年取得中科院大学地球化学硕士学位
华健2018年取得贵州师范大学环境科学硕士学位
马胜寿2018年取得广西大学凝聚态物理理学硕士学位