环境科学与工程学院-陈威导师介绍
陈威
硕,博士生导师
男
环境科学与工程学院
环境科学与工程
土壤/地下水及沉积物污染和修复、环境有机化学
chenwei@nankai.edu.cn
博士招生专业
1
环境科学与工程
2025
3
学术型博士
招生信息
1
环境科学与工程
2025
1
学术型硕士
2
环境科学与工程
2025
1
专业学位硕士
职称/职务
校特聘教授、博士生导师
天津市城市生态环境修复与污染防治重点实验室 主任
中美环境修复与可持续发展中心(China-US Center for EnvironmentalRemediation and Sustainable Development) 联合主任(Co-director)
注册资质
美国德克萨斯州注册工程师(P.E., LicensedProfessional Engineer in Texas, 90890)
研究领域
土壤/地下水及沉积物污染和修复、环境有机化学
教学经验
1)1997—1999:讲授Introductionto Environmental Chemistry (Rice大学本科生课程)
2)1999:讲授EnvironmentalOrganic Chemistry(Rice大学研究生课程)
3)2005至今:讲授《土壤及地下水污染与修复》(南开大学硕士生/博士生课程)
4)2007至今:讲授《污染生态化学》(南开大学本科生课程)
主要学术经历
1988.09—1992.07 南开大学环境科学系环境化学专业,获学士学位。
1992.09—1994.07 南开大学环境科学系环境化学专业,攻读硕士学位。
1994.08—1997.05 美国Rice大学环境科学与工程系,获硕士学位。
1997.06—2000.01 美国Rice大学环境科学与工程系,获博士学位。
1999.03—2004.08 美国Brown and Caldwell环境工程公司,工程师。
2004.02—至今 南开大学环境科学与工程学院,校特聘教授(环境科学岗位)、博士生导师;天津市城市生态环境修复与污染防治重点实验室,主任。
2004.02—至今 美国Rice大学土木与环境工程系,客座教授。
2006.02—至今 南开大学中美环境修复与可持续发展中心,主任。
2010、2019、2023 奥地利维也纳大学,客座教授。
主要学术任职
1)美国Rice大学土木与环境工程系,客座教授
2)Environmental Toxicology andChemistry, Editor(2012)
3)Environmental Science &Technology, Editorial advisory board (2017-2022)
4)Environmental Science: Nano, Advisory board (2018)
5)Science of the Total Environment, Editorial board member (2017-2022)
6)Journal of Environmental Sciences, Editorialboard member (2016)
7)Carbon Research, Editorial board member (2021)
8)《环境化学》副主编(2021)
9)《化学学报》编委(2018)
10)《环境科学》编委(2018)
11)《环境化学》编委(2009-2021)
12)《高等学校化学学报》编委(2021)
13)《高等学校化学学报》(CJCU)(2024)
14)《ChemicalResearch in Chinese Universities》(CRCU)(2024)
15)中国化学会环境化学专业委员会,副主任委员(2018.12)
16)中国环境科学学会环境化学分会,委员(2015.5)
17)中国环境科学学会土壤与地下水环境专业委员会,委员(2009.11)
18)中国生态学会污染生态专业委员会,委员(2013)
19)中国自然资源学会资源循环利用专业委员会,委员(2007.1)
20)中国地理学会环境地理专业委员会,委员(2015)
21)中国土壤学会土壤化学专业委员会,委员(2020.12)
22)Managementcommittee of International Water Association (IWA) “Nano and Water” specialistgroup, Member (2013.9)
23)环境保护部化学物质环境管理专家评审委员会,委员(2010.11)
24)天津市城建与环境领域重点实验室创新战略联盟,理事长(2012.7)
25)云南省土壤固碳与污染控制重点实验室(昆明理工),学术委员会委员(2017)
26)珠三角水质安全与保护教育部重点实验室(广州大学),学术委员会委员(2019)
27)山东省油田采出水处理及环境污染治理重点实验室学术委员会,委员(2010?)
28)广东省石油化工污染过程与控制重点实验室学术委员会,委员(2019)
29)浙江省有机污染过程与控制重点实验室学术委员会,委员(2020)
30)污染场地修复产业技术创新战略联盟专家委员会,委员(2014.9)
31)天津市生态道德教育促进会第二届专家委员会,委员(2022.4)
32)中国环境科学研究院土壤与地下水环境研究所学术委员会,委员(2023.11)
33)天津市水资源与水环境重点实验室学术委员会,委员(2024.1)
34)美国化学学会(American Chemical Society),会员
35)中国化学会,会员
36)Societyof Environmental Toxicology and Chemistry,会员
37)InternationalWater Association,会员
38)美国德克萨斯州注册工程师
社会职务
1)中国人民政治协商会议天津市第十三、十四、十五届委员会,委员
2)天津市归国华侨联合会第十届委员会,常务委员(2023-)
3)天津市归国华侨联合会第九届委员会,委员(2018-)
4)天津市政协经济社会发展研究咨询委员会,委员
5)天津市党外知识分子联谊会第二届会员(2018-)
6)天津市青年联合会第十一届委员会,委员
7)天津市政府决策咨询专家
8)天津市留学人员联谊会/天津市欧美同学会,理事
9)南开大学侨联暨留学归国人员联谊会,委员
荣誉与奖励
1)Environmental Science & Technology “Excellence inReview” award (2017)
2)高等学校科学研究优秀成果奖(科学技术)自然科学奖一等奖(2/11):“水环境中污染物的界面化学过程及机制”(2015.02)
3)天津市科学技术进步奖二等奖(5/8):“城市污染河道原位修复技术集成及应用”(2015.01)
4)天津市科学技术进步奖二等奖(2/8):“石油污染土壤革新修复技术与应用”(2014.01)
5)获得the 10th InternationalSymposium on Persistent Toxic Substances “Young Scientist Award”(2013年8月)
6)入选2008年中国百篇最具影响国际学术论文
7)入选第3批国家“万人计划”科技创新领军人才(2017)
8)入选科技部“中青年科技创新领军人才”(2015)
9)入选天津市“中青年科技创新领军人才”(2015)
10)获得“天津市优秀留学人员”荣誉称号(2009)
11)入选中国科协高层次人才库
12)入选2006年天津市“131创新型人才培养工程”第一层人选
13)入选2005年教育部“新世纪优秀人才支持计划”
14)获得2005年霍英东教育基金会高等院校青年教师基金资助
15)获得“全国侨联系统先进个人”荣耀称号(2018)
16)获得天津市政府决策咨询建议优秀建议奖(2010)
展开更多
科研项目
科研项目
1) 《环境中典型微塑料的关键界面化学过程与机制研究》,国家自然科学基金专项项目(22241602),270万元,2023/01—2026/12(项目主持人)。
2) 《工业集聚区土壤-地下水有机污染综合防治技术及应用》,国家重点研发计划“大气与土壤、地下水污染综合治理”重点专项(2022YFC3702400),4050(财政2550)万元,2022/12—2026/11(项目主持人/课题1负责人468万元)。
3) 《基于污染物选择性去除的新型污染场地修复技术研究》,南开大学天津市应用基础研究联合项目(21JCZDJC00280),20万元,2021/10—2024/09(项目主持人)。
4) 《用于污染场地地下含水层原位修复的新型纳米技术研究》,国家自然科学基金重点国际(地区)合作研究项目(22020102004),277万元,2021/01—2025/12(项目主持人)。
5) 《污染场地中持久性有机污染物的积累效应和健康风险研究及预测模型建立》,国家重点研发计划“场地土壤污染成因与治理技术”重点专项课题2,“持久性有机污染物在污染场地土壤和地下含水层中的迁移过程及主控因子”(2019YFC1804202),353万元,2020/01—2023/12(参与人/158万元)。
6) 《纳米塑料对有机污染物在饱和多孔介质中运移的影响机制研究》,国家自然科学基金面上项目(21876089),65万元,2019/01—2022/12(项目主持人)。
7) 《土壤中磺胺抗生素归趋及其与磺胺降解基因和抗性基因共存特征的相关性研究》,国家自然科学基金国际(地区)合作与交流项目(21661132004),¥2568,000,2017/01—2020/12(第一参加人)。
8) 《全氟化合物异构体指纹识别技术研发与应用平台建设》,天津市科技计划创新平台与人才计划项目(17JCYBJC23200),¥400,000,2016.09—2018.12(第一参加人)。
9) 《有机污染物环境界面化学》,国家杰出青年科学基金(21425729),¥4,000,000,2015/01—2019/12(项目主持人)。
10) 《人工纳米材料在环境中的迁移、转化和归趋研究》,国家重点基础研究发展计划(973计划)项目《典型人工纳米材料的水环境过程、生物效应及其调控研究》课题1——“人工纳米材料在环境中的迁移、转化和归趋研究”(2014CB932001),¥4,510,000,2014/01—2018/12(课题负责人)。
11) 《人工纳米材料对水环境中有机污染物界面过程的影响机制研究》,国家自然科学基金重点项目(21237002),¥3,000,000,2013/01—2017/12(项目主持人)。
12) 《新型人工纳米材料的环境过程及环境影响研究》,教育部学校特色项目,¥400,000,2012年06月—2014年06月(项目主持人)。
13) 《中美环境修复与可持续发展国际科技合作基地建设》,天津市科技支撑计划国际科技合作项目(12HZGJHZ01100),¥200,000,2012/10—2014/09(项目主持人)。
14) 《稳定碳纳米颗粒悬浮物对于有机污染物在饱和多孔介质中运移行为的影响》,国家自然科学基金面上项目(21177063),¥700,000,2012/01—2015/12(项目主持人)。
15) 《基于碳纳米材料的高效柔性太阳能电池和超级电容器研制》,国际科技合作与交流专项(2011DFB50300),¥6,000,000,2011/01—2013/12(第一参加人)。
16) 《天津市重点实验室建设—利用新型纳米技术去除水中难降解有机污染物》,天津市科技创新体系及条件平台建设计划项目(10SYSYJC27200),¥1,000,000,2010/04—2013/03(项目主持人)。
17) 《极性有机污染物与碳基纳米材料的特殊作用对不可逆吸附的影响》,国家自然科学基金面上项目(20977050),¥360,000,2010/01—2012/12(项目主持人)。
18) 《中新生态城环境治理与生态修复关键技术研究及示范》课题一《湖库重污染底泥处理处置及资源化利用关键技术集成与工程示范》,国家科技支撑计划项目(2009BAC60B01),¥9,620,000(南开¥360,000),2009/07—2012/07(参加人)。
19) 《水溶液中富勒烯稳定团聚体的形貌和表面化学性质对于富勒烯—污染物吸附作用的影响机制》,国家自然科学基金外国青年学者研究基金(21150110140),¥200,000,2011/07—2012/06(国内合作者)。
20) 《利用新型纳米技术去除饮用水中藻毒素和内分泌干扰物的研究》,教育部高等学校科技创新工程重大项目培育资金项目(708020),¥400,000,2009/01—2011/12(项目主持人)。
21) 《水体沉积物环境质量基准及原位修复关键技术研究》,国际科技合作项目(2009DFA91910),¥1,000,000,2009/01—2010/12(项目主持人)。
22) 《中新生态城水污染整治关键技术研究—受污染沉积物的原位修复技术研究》(08ZCGHHZ01000),天津市科技支撑计划国际科技合作项目,¥100,000,2009/01—2010/12(第一参加人)。
23) 《大沽排污河污染河道原位修复技术集成及应用》,天津市科技创新专项资金项目课题2(08FDZDSF03400),¥3,000,000,2008/10—2010/12(项目主持人)。
24) 《油田区石油污染土壤生态修复技术与示范》,国家高技术研究发展计划(863计划)重点项目(2007AA061200),¥6,840,000,2007/07—2010/12(项目主持人)。
25) 《土壤中持久性有机有毒污染物的迁移转化规律及对地下水的影响》,国家自然科学基金重点项目(20637030),¥2,000,000,2007/01—2010/12(第一参加人)。
26) 《污染沉积物的活性反应格栅原位修复技术与机理的研究》,天津市应用基础及前沿技术研究计划重点项目(07JCZDJC01900),¥500,000,2007/04—2010/03(第一参加人)。
27) 《吸附态1,1,2,2-四氯乙烷的非生物降解机理》,教育部高等学校博士学科点专项科研基金(20060055035),¥60,000,2007/01—2009/12(项目主持人)。
28) 《中美环境修复与可持续发展中心联合实验室建设》,天津市科技支撑计划重点项目(07ZCGHHZ00300),¥200,000,2007/10—2009/09(项目主持人)。
29) 《天津地区土壤中典型有机污染物环境标准与污染控制技术研究》,天津市科技发展计划科技创新能力与环境建设平台项目,(06TXTJJC14000),¥1,000,000,2006/07—2009/06(项目主持人)。
30) 《中新天津生态城污水库底泥处置风险评估》,天津市市政工程设计研究院,¥600,000,2008/10—2009/04(第一参加人)。
31) 《土壤中被锁定有机污染物的反应活性》,国家自然科学基金面上项目(20577024),¥260,000,2006/01—2008/12(项目主持人)。
32) 《土壤和沉积物中被锁定有机污染物的生物可利用性》,霍英东教育基金会高等院校青年教师基金项目(101081),$20,000,2005/07—2008/06(项目主持人)。
33) 《土壤和沉积物中持久性有机污染物的生物可利用性》,国家自然科学基金面上项目(20407013),¥250,000,2005/01—2007/12(项目主持人)。
34) 《土壤/沉积物中持久性有机污染物的生物可利用性》,教育部科学技术研究重点项目(105044),¥100,000,2005/01—2007/12(项目主持人)。
35) 《 土壤/沉积物中被锁定有机污染物的生物可利用性》,教育部留学回国人员科研启动基金,¥30,000(项目主持人)。
主要工程项目
1) “有机氯农药、砷类化合物及有机氯溶剂在土壤和地下水中的分布特征及污染发生机理调查”,休斯敦港,$500,000,1999/09—2002/12。
2) “有机氯农药污染土壤和地下水的原位修复可行性研究及修复工程设计”, 休斯敦港,$500,000,2003/03—2004/08。
3) “地下石油储罐泄漏治理、产品回收及土壤修复”,Koch公司Corpus Christi炼油厂,$200,000,2000/01—2003/04。
4) “BTEX和有机氯溶剂的自然净化及生物降解可行性研究”,Oakite Products公司,$35,000,2000/05—2001/04。
5) “利用零价铁反应栅处理地下水中有机氯溶剂污染”,Oakite Products公司,$150,000,2002/05—2003/12。
6) “污染沉积物综合治理可行性研究和现场测试”,休斯敦港,$250,000,2000/07—2004/02。
7) “三维地下水流动及污染物迁移转化数学模型设计”,休斯敦港,$250,000,1999/03—2003/05。
8) “地下水资源开发利用方案研究中数学模型的建立”,El Paso市政府,$50,000,2000/12—2001/05。
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研究成果
学术论文
1) Liang, Zongsheng; Liu, Keman; Li, Yueyue; Liu, Yaqi; Jiang, Chuanjia*, Zhang, Tong*; Chen, Wei. “Oxygen vacancies boost the efficacy of MnO2 nanoparticles in catalyzing hydrolytic degradation of organophosphate esters: Implications for managing plastic additive pollution,” Environmental Science: Nano, 2024, in press.
2) Pei, Xule; Wang, Weichao; Chen, Zaihao; Liu, Keman; Liang, Zongsheng; Jiang, Chuanjia*; Zhang, Tong*; Chen, Wei. “Metal heteroatoms significantly enhance efficacy of TiO2 nanomaterials in promoting hydrolysis of organophosphates: Implications for mitigating pollution of plastic additives,” Science of the Total Environment, 2024, in press.
3) Cao, Tianchi; Zhao, Mengting; Zhang, Tong*; Chen, Wei. “Weathering Pathways Differentially Affect Colloidal Stability of Nanoplastics,” Environmental Science: Nano, 2024, in press.
4) Du, Tingting; Guan, Wenyu; Zhang, Zhanhua; Jiang, Chuanjia; Alvarez, Pedro; Chen, Wei; Zhang Tong*. “Facet-Dependent Oxysulfidation of Cu2O Nanomaterials: Implications for Improving the Efficacy of Nanopesticides,” Environmental Science: Nano, 2024, in press.
5) Zhang, Zhiying; Zhang, Zhanhua; Zhang, Chenyang; Chang, Qing; Fang, Qingxuan; Liao, Chengmei; Chen, Jiubin; Alvarez, Pedro; Chen, Wei; Zhang Tong*. “Simultaneous Reduction and Methylation of Nanoparticulate Mercury: The Critical Role of Extracellular Electron Transfer,” Environmental Science & Technology, 2024, in press.
6) Tong, Xin; Zhang, Zhanhua; Dong, Xiaoyin; Guan, Wenyu; Liu, Zhenhai Liu; Chen, Jiubin; Alvarez, Pedro; Chen, Wei; Zhang Tong*. “Sulfur-Intercalated Layered Double Hydroxides Minimize Microbial Mercury Methylation: Implications for In Situ Remediation of Mercury Contaminated Sites,” Environmental Science & Technology, 2024, in press.
7) Cao, Tianchi; Liu, Yaqi; Gao, Cheng; Yuan, Yuxin; Chen, Wei; Zhang Tong*. “Understanding Nanoscale Interactions between Minerals and Microbes: Opportunities for Green Remediation of Contaminated Sites,” Environmental Science & Technology, 2024, in press.
8) Guan, Wenyu; Zhang, Zhanhua; Liu, Yaqi; Ji, Yunyun; Tong, Xin; Liu, Yaqi; Chen, Jiubin: Alvarez, Pedro; Chen, Wei; Zhang Tong*. “Crystalline Phase Regulates Microbial Methylation Potential of Mercury Bound to MoS2 Nanosheets: Implications for Safe Design of Mercury Removal Materials,” Environmental Science & Technology, 2024, in press.
9) Liang, Zongsheng; Jiang, Chuanjia*; Li, Yueyue; Liu, Yaqi; Yu, Jiaguo; Zhang, Tong; Alvarez, Pedro J. J.; Chen, Wei. “Single-Atom Iron Can Steer Atomic Hydrogen toward Selective Reductive Dechlorination: Implications for Remediation of Chlorinated Solvents-Impacted Groundwater,” Environmental Science & Technology, 2024, in press.
10) Qi, Yu; Guan, Wenyu; Jiang, Chuanjia*; Chen, Wei; Zhang, Tong*. “Protein Corona Formation on Cadmium-Bearing Nanoparticles: Important Role of Facet-Dependent Binding of Cysteine-Rich Proteins,” Environment & Health, 2024, in press.
11) Zhu, Panpan; Hou, Shengli; Liu, Zhenhai; Zhou, Yinzhu; Alvarez, Pedro J. J.; Chen, Wei; Zhang, Tong*. “Multi-Emission Carbon Dots Combining Turn-on Sensing and Fluorescence Quenching Exhibit Ultrahigh Selectivity for Mercury in Real Water Samples,” Environmental Science & Technology, 2024, in press.
12) Liu, Jiameng; Cao, Tianchi*; Duan, Lin; Xu, Shengkai; Li, Min; Zhang, Tong*; Chen, Wei*. “Co-Transport of Polybromodiphenyl Ethers and Soil Nanoparticles in Saturated Porous Media: Implications for the Risks of Polybromodiphenyl Ether Spreading in Groundwater,” Environmental Science: Nano, 2024, 11, 2568 - 2576.
13) Li, Tong; Ju, Yiting; Du, Tingting; Jiang, Chuanjia*; Zhang, Tong*; Chen, Wei*. “Anatase TiO2 nanomaterials are much more effective in enhancing hydrolysis of organophosphorus compounds than their rutile counterparts,” Environmental Science: Nano, 2024, 11, 2447–2456.
14) Liu, Zhenhai; Yang, Qihong; Zhu, Panpan; Liu, Yaqi; Tong, Xin; Cao, Tianchi; Tomson, Mason B.; Alvarez, Pedro J. J.; Zhang, Tong*; Chen, Wei. “Cr(Ⅵ) reduction and sequestration by FeS nanoparticles formed in situ as aquifer material coating to create a regenerable reactive zone,” Environmental Science & Technology, 2024, in press.
15) Li, Yueyue; Huo, Zebin; Ying, Yuqin; Duan, Lin; Jiang, Chuanjia*; Chen, Wei. “Effects of transient flow conditions on colloid-facilitated release of decabromodiphenyl ether: Implications for contaminant mobility at e-waste recycling sites,” Eco-Environment & Health, 2024, in press.
16) Yang, Cuiyi; Duan, Lin*; Wang, Jing; Jiang, Chuanjia; Zhang, Tong; Chen, Wei*. “Preferential association of PBDEs and PAHs with mineral particles vs. dissolved organic carbon: Implications for groundwater contamination at e-waste sites,” Journal of Environmental Sciences, 2024, in press.
17) Duan, Lin; Liu, Jiahuan; Wang, Jing; Jiang, Chuanjia*; Zhang, Tong; Chen, Wei. “A screening model for predicting the potential of soil colloids-enhanced leaching of hydrophobic organic contaminants to groundwater at contaminated sites,” Journal of Environmental Sciences, 2024, in press.
18) Xu, Xiaojie; Goros, Ria A.; Dong, Zheng; Meng, Xin; Li, Guangle; Chen, Wei; Liu, Sijin; Ma, Juan*; Zuo, Yi Y.*. “Microplastics and Nanoplastics Impair the Biophysical Function of Pulmonary Surfactant by Forming Heteroaggregates at the Alveolar–Capillary Interface,” Environmental Science & Technology, 2023, 57, 50, 21050–21060.
19) Duan, Lin; Li, Min; Liu, Jiameng; Chen, Wei*. “Soil colloids can significantly enhance spreading of polybromodiphenyl ethers in groundwater by serving as an effective carrier,” Journal of Environmental Sciences, 2023, in press.
20) Huo, Zebin; Xi, Mengjun; Xu, Lianrui; Jiang, Chuanjia*; Chen, Wei. “Colloid-facilitated release of polybrominated diphenyl ethers at an e-waste recycling site: Evidence from undisturbed soil core leaching experiments,” Frontiers of Environmental Science & Engineering, 2023, in press.
21) Shen, Meimei; Liu, Songlin; Jiang, Chuanjia*; Zhang, Tong; Chen, Wei. “Recent advances in stimuli-response mechanisms of nano-enabled controlled-release fertilizers and pesticides,” Eco-Environment & Health, 2023, in press.
22) Duan, Lin; Zhong, Jingyi; Ying, Yuqin; Jiang, Chuanjia; Chen, Wei*. “Preferential association of polycyclic aromatic hydrocarbons (PAHs) with soil colloids at an e-waste recycling site: Implications for risk of PAH migration to subsurface environment,” Science of the Total Environment, 2023, in press.
23) Yunyun Ji, Shan Gao, Rui Si, Zhanhua Zhang, Li Tian, Wenyu Guan, Weichao Wang, Wei Chen, Pedro J. J. Alvarez, Tong Zhang*. “Structural incorporation of iron influences biomethylation potential of mercury sulfide,” Geochimica et Cosmochimica Acta, in press.
24) Duan, Lin; Qin, Yiyuan; Meng, Xin; Liu, Yaqi; Zhang, Tong; Chen, Wei*. “Sulfide- and UV-induced aging differentially affect contaminant-binding properties of microplastics derived from commercial plastic products,” Science of the Total Environment, 2023, 869, 161800.
25) Ma, Pengkun; Qi, Zhichong*; Wu, Xuan; Ji, Rong; Chen, Wei. “Biochar nanoparticles-mediated transport of organic contaminants in porous media: dependency on contaminant properties and effects of biochar aging,” Carbon Research, 2023, 2:4.
26) Zhu, Meiling; Zhang, Zhanhua; Zhang, Tong; Hofmann, Thilo; Chen, Wei*. “Eco-corona Dictates Mobility of Nanoplastics in Saturated Porous Media: The Critical Role of Preferential Binding of Macromolecules,” Environmental Science & Technology, 2023, 57, 1, 331–339.
27) Liu, Yaqi; Gan, Haibo; Tian, Li; Liu, Zhenhai; Ji, Yunyun; Zhang, Tong*; Alvarez, Pedro; Chen, Wei. “Partial oxidation of FeS nanoparticles enhances Cr(VI) sequestration,” Environmental Science & Technology, 2022, 56, 19, 13954–13963.
28) Xiaodong Ma*, Xiaoyao Liu, Haiwei Guo, Gengbo Ren, Jiaxin Wen, Wei Chen*, Guichang Wang. “Catalytic Activity, Water Resistance and Stability of Hematite Nanomaterials in Oxidative Removal of Polychlorinated Aromatic Hydrocarbons Can Be Simultaneously Enhanced through Facet Engineering,” Environmental Science: Nano, 2022, 9, 3780–3788.
29) Jiang, Chuanjia; Liu, Songlin; Zhang, Tong*; Liu, Qian*; Alvarez, Pedro; Chen, Wei. “Current Methods and Prospects for Analysis and Characterization of Nanomaterials in the Environment,” Environmental Science & Technology, in press.
30) Gabriel Sigmund, Hans Peter H. Arp, Benedikt M. Aumeier, Thomas D. Bucheli, Benny Chefetz, Wei Chen, Steven T. J. Droge, Satoshi Endo, Beate I. Escher, Sarah E. Hale, Thilo Hofmann, Joseph Pignatello, Thorsten Reemtsma, Torsten C. Schmidt, Carina D. Schönsee, Martin Scheringer. “Sorption and Mobility of Charged Organic Compounds: How to Confront and Overcome Limitations in Their Assessment,” Environmental Science & Technology, in press.
31) Fu, Di; Duan, Lin*; Li, Xiaoyan; Jiang, Chuanjia; Zhang, Tong; Chen, Wei*. “Citrate-promoted dissolution of nanostructured manganese oxides: Implications for nano-enabled sustainable agriculture,” Journal of Environmental Sciences, 2022, in press.
32) Duan, Lin; Ying, Yuqin; Zhong, Jingyi; Jiang, Chuanjia; Chen, Wei*. “Key factors controlling colloids–bulk soil distribution of polybrominated diphenyl ethers (PBDEs) at an e-waste recycling site: Implications for PBDE mobility in subsurface environment,” Science of the Total Environment, 2022, 819, 153080.
33) Ma, Pengkun; Yang, Cuiyi; Zhu, Meiling; Fan, Lihua; Chen, Wei*. “Leaching of Organic Carbon Enhances Mobility of Biochar Nanoparticles in Saturated Porous Media,” Environmental Science: Nano, 2021, 8, 2584 - 2594.
34) Juan Ma; Xinlei Liu; Yi Yang; Jiahuang Qiu; Zheng Dong; Quanzhong Ren; Yi Y. Zuo; Tian Xia; Wei Chen*; Sijin Liu*. 2021, “Binding of Benzo[a]pyrene Alters the Bio-reactivity of Fine Biochar Particles towards Macrophages Leading to Deregulated Macrophagic Defense and Autophagy,” ACS Nano, 15, 6, 9717–9731.
35) Yanfeng Wang; Yeming Xu; Shangshang Dong; Peng Wang; Wei Chen; Zhenda Lu; Deju Ye; Bingcai Pan; Di Wu; Chad Vecitis; Guandao Gao*. 2021, “Ultrasonic activation of inert poly(tetrafluoroethylene) enables piezocatalytic generation of reactive oxygen species,” Nature Communications, 12, 3508.
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37) Tian, Li; Guan, Wenyu; Ji, Yunyun; He, Xin; Chen, Wei; Alvarez, Pedro; Zhang, Tong*. 2021, “Microbial methylation potential of mercury sulfide particles dictated by surface structure,” Nature Geoscience, 14: 409-416.
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39) Liu, Xinlei; Ma, Juan; Ji, Rong; Wang, Songfeng; Zhang, Qiurong; Zhang, Chengdong; Liu, Sijin*; Chen, Wei*. 2021, “Biochar Fine Particles Enhance Uptake of Benzo(a)pyrene to Macrophages and Epithelial Cells via Different Mechanisms,” Environmental Science & Technology Letters, 8, 3, 218–223.
40) Chang, Qing; Zhang, Zhanhua; Ji, Yunyun; Tian, Li; Chen, Wei; Zhang, Tong*. 2020, “Natural Organic Matter Facilitates formation and Microbial Methylation of Mercury Selenide Nanoparticles,” Environmental Science: Nano, 8: 67-75.
41) Fu, Di; Duan, Lin*; Jiang, Chuanjia; Zhang, Tong; Chen, Wei*. 2020, “Nanostructured Manganese Oxides Exhibit Facet-Dependent Oxidation Capabilities,” Environmental Science: Nano, 7: 3840 - 3848.
42) Liu, Mingyang; Yu, Qilin; Chen, Wei; Liu, Xiangsheng; Alvarez, Pedro. 2020, “Engineering of CoSe2 Nanosheets via Vacancy Manipulation for Efficient Cancer Therapy,” ACS Applied Bio Materials, 3, 11, 7800–7809.
43) Liu, Xinlei; Gharasoo, Mehdi; Shi, Yu; Sigmund, Gabriel; Hüffer, Thorsten; Duan, Lin; Wang, Yongfeng; Ji, Rong*; Hofmann, Thilo; Chen, Wei*. 2020, “Key Physicochemical Properties Dictating Gastrointestinal Bioaccessibility of Microplastics-Associated Organic Xenobiotics: Insights from a Deep Learning Approach,” Environmental Science & Technology, 54, 19, 12051-12062.
44) Sergi Garcia-Segura, Xiaolei Qu, Pedro J.J. Alvarez, Brian P. Chaplin, Wei Chen, John C Crittenden, Yujie Feng, Guandao Gao, Zhen He, Chia-Hung Hou, Xiao Hu, Guibin Jiang, Jae-Hong Kim, Jiansheng Li, Qilin Li, Jie Ma, Jinxing Ma, Alec Brockway Nienhauser, Junfeng Niu, Bingcai Pan, Xie Quan, Filippo Ronzani, Dino Villagran, T. David Waite, W. Shane Walker, Can Wang, Michael S. Wong, Paul Westerhoff. 2020, “Opportunities for Nanotechnology to Enhance Electrochemical Treatment of Pollutants in Potable Water and Industrial Wastewater - A perspective,” Environmental Science: Nano, 7, 2178–2194.
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47) Yu, Qilin; Wu, Guizhu; Zhang, Tong; Zhao, Xudong; Zhou, Zhen; Liu, Lu*; Chen, Wei*; Alvarez, Pedro*. 2020, “Targeting specific cell organelles with different-faceted nanocrystals that are selectively recognized by organelle-targeting peptides,” Chemical Communications, 56, 7613 - 7616.
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49) Qi, Yu; Zhang, Tong*; Jing, Chuanyong; Liu, Sijin; Zhang, Chengdong; Alvarez, Pedro*; Chen, Wei. 2020, “Nanocrystal Facet Modulation to Enhance Transferrin Binding and Cellular Delivery,” Nature Communications, 11, 1262.
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60) Zhang, Tong; Lowry, Gregory*; Capiro, Natalie; Chen, Jianmin; Chen, Wei; Chen, Yongsheng; Dionysiou, Dionysios; Elliott, Daniel; Ghoshal, Subhasis; Hofmann, Thilo; Hsu-Kim, Heileen; Hughes, Joseph; Jiang, Chuanjia; Jiang, Guibin; Jing, Chuanyong; Kavanaugh, Michael; Li, Qilin; Liu, Sijin; Ma, Jie; Pan, Bingcai; Phenrat, Tanapon; Qu, Xiaolei; Quan, Xie; Saleh, Navid; Vikesland, Peter; Wang, Qiuquan; Westerhoff, Paul; Wong, Michael; Xia, Tian; Xing, Baoshan; Yan, Bing; Zhang, Lunliang; Zhou, Dongmei; Alvarez, Pedro. 2019, “In situ remediation of subsurface contamination: Opportunities and challenges for nanotechnology and advanced materials,” Environmental Science: Nano, 6, 5, 1283−1302.
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66) Duan, Lin; Zhang, Tong; Song, Weihua; Jiang, Chuanjia, Hou, Yan; Zhao, Weilu; Chen, Wei*, Alvarez, Pedro. 2018, “Photolysis of Graphene Oxide in the Presence of Nitrate: Implications for Graphene Oxide Integrity in Water and Wastewater Treatment,” Environmental Science: Nano, 6, 136 - 145.
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70) Liu, Sijin*; Lv, Yonglong; Chen, Wei*. 2018, “Bridge Knowledge Gaps in Environmental Health and Safety for Sustainable Development of Nano-industries,” Nano Today, 23, 11-15.
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75) Guo, Sheng-qi; Zhu, Xiao-he; Zhang, Hai-jun; Gu, Bing-chuan; Chen, Wei*; Liu, Lu*; Alvarez, Pedro*. 2018, “Improving Photocatalytic Water Treatment through Nanocrystal Engineering: Mesoporous Nanosheet-Assembled 3D BiOCl Hierarchical Nanostructures That Induce Unprecedented Large Vacancies,” Environmental Science & Technology, 52, 12, 6872−6880.
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98) Liu, Lu; Sun, Mei-Qing; Zhang, Haijun; Yu, Qilin; Li, Mingchun; Qi, Yu; Zhang, Chengdong; Gao, Guandao; Yuan, Ying-Jin; Zhai, Huanhuan; Chen, Wei; Alvarez, Pedro. 2016, “Facet Energy and Reactivity versus Cytotoxicity: the Surprising Behavior of CdS Nanorods,” Nano Letters, 16(1):688-694.
99) Xia, Tianjiao; Fortner, John; Zhu, Dongqiang; Qi, Zhichong; Chen, Wei. 2015, “Transport of Sulfide-Reduced Graphene Oxide in Saturated Quartz Sand: Cation-Dependent Retention Mechanisms,” Environmental Science & Technology, 49(19): 11468-11475.
100) Zhang, Chengdong; Chen, Silong; Alvarez, Pedro; Chen, Wei. 2015, “Reduced Graphene Oxide Enhances Horseradish Peroxidase Stability by Serving as Radical Scavenger and Redox Mediator,” Carbon, 94, 531–538..
101) Wang, Fanfan; Wang, Fang; Gao, Guandao; Chen, Wei. 2015, “Transformation of Graphene Oxide by Ferrous Iron: Environmental Implications,” Environmental Toxicology and Chemistry, 34 (9), 1975–1982.
102) Pan, Meilan; Zhang, Haijun; Gao, Guandao; Liu, Lu; Chen, Wei. 2015, “Facet-Dependent Catalytic Activity of Nanosheets-Assembled BiOI Microspheres in Degradation of Bisphenol A,” Environmental Science & Technology, 49 (10), 6240–6248.
103) Wang, Fanfan; Wang, Fang; Zhu, Dongqiang; Chen, Wei. 2015, “Effects of Sulfide Reduction on Adsorption Affinities of Colloidal Graphene Oxide Nanoparticles for Phenanthrene and 1-Naphthol,” Environmental Pollution, 196, 371–378.
104) Fu, Heyun; Qu, Xiaolei; Chen, Wei; Zhu, Dongqiang. 2014, “Transformation and Destabilization of Graphene Oxide in Reducing Aqueous Solutions Containing Sulfide,” Environmental Toxicology and Chemistry, 33 (12), 2647–2653.
105) Qi, Zhichong; Zhang, Lunliang; Chen, Wei. 2014, “Transport of Graphene Oxide Nanoparticles in Saturated Sandy Soil,” Environmental Science: Processes & Impacts, 16 (10), 2268–2277.
106) Qi, Zhichong; Hou, Lei; Zhu, Dongqiang; Ji, Rong; Chen, Wei. 2014, “Enhanced Transport of Phenanthrene and 1-Naphthol by Colloidal Graphene Oxide Nanoparticles in Saturated Soil,” Environmental Science & Technology, 48, 10136–10144.
107) Wang, Bingyu; Chen, Wei; Fu, Heyun; Qu, Xiaolei; Zheng, Shourong; Xu, Zhaoyi; Zhu, Dongqiang. 2014, “Comparison of Adsorption Isotherms of Single-Ringed Compounds between Carbon Nanomaterials and Porous Carbonaceous Materials over Six-Order-of-Magnitude Concentration range,” Carbon, 79, 203–212.
108) Chen, Weifeng; Li, Yao; Zhu, Dongqiang; Zheng, Shourong; Chen, Wei. 2014, “Dehydrochlorination of Activated Carbon-Bound 1,1,2,2-Tetrachloroethane: Implications for Carbonaceous Material-Based Soil/Sediment Remediation,” Carbon, 78, 578–588.
109) Wang, Zhongyuan; Duan, Lin; Zhu, Dongqiang; Chen, Wei. 2014, “Effects of Cu(II) and Ni(II) Ions on Adsorption of Tetracycline to Functionalized Carbon Nanotubes,” Journal of Zhejiang University-SCIENCE A, 15, 8, 653−661.
110) Zhang, Chengdong; Chen, Wei; Alvarez, Pedro. 2014, “Manganese Peroxidase Degrades Pristine but Not Surface-Oxidized (Carboxylated) Single-Walled Carbon Nanotubes,” Environmental Science & Technology, 48, 7918–7923.
111) Mauter, Meagan; Alvarez, Pedro; Burton, G. Allen; Cafaro, Diego; Chen, Wei; Gregory, Kelvin; Jiang, Guibin; Li, Qilin; Pittock, Jamie; Reible, Danny; Schnoor, Jerald. 2014, “Regional Variation in Water-Related Impacts of Shale Gas Development and Implications for Emerging International Plays,” Environmental Science & Technology, 48, 8298–8306.
112) Chen, Weifeng; Zhu, Dongqiang; Zheng, Shourong; Chen, Wei. 2014, “Catalytic Effects of Functionalized Carbon Nanotubes on Dehydrochlorination of 1,1,2,2-Tetrachloroethane,” Environmental Science & Technology, 48, 3856–3863.
113) Duan, Lin; Li, Lingfang; Xu, Zhu; Chen, Wei. 2014, “Adsorption of Tetracycline to Nano-NiO: Effect of Co-existing Cu(II) Ion and Environmental Implications,” Environmental Science: Processes & Impacts, 16, 1462–1468.
114) Liu, L.; Sun, M.; Li, Q.; Zhang, H.; Alvarez, P.; Liu, H.; Chen, W. 2014, “Genotoxicity and cytotoxicity of CdS nanomaterials to mice: comparison between nanorods and nanodots,” Environmental Engineering Science, 31(7): 373-380.
115) Qi, Z.; Zhang, L.; Wang, F.; Hou, L.; Chen, W. 2014, “Factors controlling transport of graphene oxide nanoparticles in saturated sand columns,” Environmental Toxicology and Chemistry, 33, 5, 998–1004.
116) Wang, L.; Hou, L.; Wang, X.; Chen, W. 2014, “Effects of Preparation Method and Humic-Acid Modification on Mobility and Contaminant-Mobilizing Capability of Fullerene Nanoparticles (nC60),” Environmental Science: Processes & Impacts, 16, 1282–1289.
117) Fu, H.; Guo, Y.; Chen, W.; Gu, C.; Zhu, D. 2014, “Reductive Dechlorination of Hexachloroethane by Sulfide in Aqueous Solutions Mediated by Graphene Oxide and Carbon Nanotubes,” Carbon, 72, 74–81.
118) Wang, F.; Ji, R.; Jiang, Z.; Chen, W. 2014, “Species-Dependent Effects of Biochar Amendment on Bioaccumulation of Atrazine in Earthworms,” Environmental Pollution, 186, 241–247.
119) Wang, F.; Haftka, J.; Sinnige, T.; Hermens, J.; Chen, W. 2014, “Adsorption of Polar, Nonpolar, and Substituted Aromatics to Colloidal Graphene Oxide Nanoparticles,” Environmental Pollution, 186, 226–233.
120) Xie, M.; Chen, W.; Xu, Z.; Zheng, S.; Zhu, D. 2014, “Adsorption of Sulfonamides to Demineralized Pine Wood Biochars Prepared under Different Thermochemical Conditions,” Environmental Pollution, 186, 187–194.
121) Zhang, D.; Hou, L.; Zhu, D.; Chen, W. 2014, “Synergistic Role of Different Soil Components in Slow Sorption Kinetics of Polar Organic Contaminants,” Environmental Pollution, 184, 123–130.
122) Qiao, J.; Zhang, C.; Luo, S.; Chen, W. 2014, “Bioremediation of Highly Contaminated Oilfield Soil: Bioaugmentation for Enhancing Aromatic Compounds Removal”, Frontiers of Environmental Science & Engineering, 8(2), 293–304.
123) Xie, M.; Lv, D.; Shi, X.; Wan, Y.; Chen, W.; Mao, J.; Zhu, D. 2013, “Sorption of Monoaromatic Compounds to Heated and Unheated Coals, Humic Acid, and Biochar: Implication for Using Combustion Method to Quantify Sorption Contribution of Carbonaceous Geosorbents in Soil,” Applied Geochemistry, 35, 289–296.
124) Zhang, C.; Luo, S.; Chen, W. 2013, “Activity of Catalase Adsorbed to Carbon Nanotubes: Effects of Carbon Nanotube Surface Properties,” Talanta 113, 142–147.
125) Hou, L.; Zhu, D.; Wang, X.; Wang, L.; Zhang, C.; Chen, W. 2013, “Adsorption of Phenanthrene, 2-Naphthol, and 1-Naphthylamine to Colloidal Oxidized Multi-Walled Carbon Nanotubes: Effects of Humic Acid and Surfactant Modification,” Environmental Toxicology and Chemistry, 32, 3, 493–500.
126) Wang, L.; Fortner, J.; Hou, L.; Zhang, C.; Kan, A.T.; Tomson, M.B.; Chen, W. 2013, “Contaminant-Mobilizing Capability of Fullerene Nanoparticles (nC60): Effect of Solvent-Exchange Process in nC60 Formation,” Environmental Toxicology and Chemistry, 32, 2, 329–336.
127) Ji, L.; Chen, W.; Xu, Z.; Zheng, S.; Zhu, D. 2013, “Graphene Nanosheets and Graphite Oxide as Promising Adsorbents for Removal of Organic Contaminants from Aqueous Solution,” Journal of Environmental Quality, 42, 1, 191–198.
128) Zhang, H.; Ge, M.; Yang, L.; Zhou, Z.; Chen, W.; Li, Q.; Liu, L. 2013, “Synthesis and Catalytic Properties of Sb2S3 Nanowire-Bundle as Counter Electrode for Dye-Sensitized Solar Cells,” Journal of Physical Chemistry C,117, 10285–10290.
129) Zhang, L.; Hou, L.; Wang, L.; Kan, A.T.; Chen, W.; Tomson, M.B. 2012, “Transport of Fullerene Nanoparticles (nC60) in Saturated Sand and Sandy Soil: Controlling Factors and Modeling,” Environmental Science & Technology, 46, 13, 7230–7238.
130) Wang, L.; Huang, Y.; Kan, A.T.; Tomson, M.B.; Chen, W. 2012, “Enhanced Transport of 2,2',5,5'-Polychlorinated Biphenyl by Natural Organic Matter (NOM) and Surfactant-Modified Fullerene Nanoparticles (nC60),” Environmental Science & Technology, 46, 10, 5422–5429.
131) Zhang, L.; Zhu, D.; Wang, H.; Hou, L.; Chen, W. 2012, “Humic Acid-Mediated Transport of Tetracycline and Pyrene in Saturated Porous Media,” Environmental Toxicology and Chemistry, 31, 3, 534–541.
132) Wang, F.; Zhu, D.; Chen, W. 2012, “Effect of Copper Ion on Adsorption of Chlorinated Phenols and 1-Naphthylamine to Surface-Modified Carbon Nanotubes,” Environmental Toxicology and Chemistry, 31, 1, 100–107.
133) Lv, D.; Wan, Y.; Shi, X.; Xu, H.; Chen, W.; Zhu, D. 2012, “Effect of Heat Treatment on Sorption of Polar and Nonpolar Compounds to Montmorillonites and Soils,” Journal of Environmental Quality, 41, 4, 1284–1289.
134) Yang, W.; Lampert, D.; Zhao, N.; Reible, D.; Chen, W. 2012, “Link between Black Carbon and Resistant Desorption of PAHs on Soil and Sediment,” Journal of Soils and Sediments, 12, 5, 713–723.
135) Yang, W.; Zhao, N.; Zhang, N.; Chen, W.; Kan, A.; Tomson, M. 2012, “Time-Dependent Adsorption and Resistant Desorption of Arsenic on Magnetite Nanoparticles: Kinetics and Modeling,” Desalination and Water Treatment, 44, 100–109.
136) Zhang, H.; Yang, L.; Liu, Z.; Ge, M.; Zhou, Z.; Chen, W.; Li, Q.; Liu, L. 2012, “Facet-Dependent Activity of Bismuth Sulfide as Low-Cost Counter-Electrode Materials for Dye-Sensitized Solar Cells,” Journal of Materials Chemistry, 22, 18572–18577.
137) Ge, M.; Liu, L.; Chen, W.; Zhou, Z. 2012, “Sunlight-Driven Degradation of Rhodamine B by Peanut-Shaped Porous BiVO4 Nanostructures in the H2O2-Containing System,” CrystEngComm, 14(3), 1038–1044.
138) Wang, J.; Liu, Z.; Yuan, S.; Liu, L.; Zhou, Z.; Chen, W. 2012, “Uniform Chrysanthemum-Like Bi2S3 Microspheres for Dye-Sensitised Solar Cells,” Australian Journal of Chemistry, 65, 9, 1342–1348.
139) Tang, H.; Zhu, D.; Li, T.; Kong, H.; Chen, W. 2011, “Reductive Dechlorination of Activated Carbon-Adsorbed Trichloroethylene by Fe(0): Carbon as Electron Shuttle,” Journal of Environmental Quality, 40, 6, 1878–1885.
140) Zhang, L.; Wang, L.; Zhang, P.; Kan, A.T.; Chen, W.; Tomson, M.B. 2011, “Facilitated Transport of 2,2’,5,5’-Polychlorinated Biphenyl and Phenanthrene by Fullerene Nanoparticles through Sandy Soil Columns,” Environmental Science & Technology, 45, 4, 1341–1348.
141) Berlin, J.; Yu, J.; Lu, W.; Walsh, E.; Zhang, L.; Zhang, P.; Chen, W.; Kan, A.; Wong, M.; Tomson, M.; Tour, J. 2011, “Engineered Nanoparticles for Hydrocarbon Detection in Oil-field Rocks,” Energy & Environmental Science, 4, 2, 505–509.
142) Lian, F.; Huang, F.; Chen, W.; Xing, B.; Zhu, L. 2011, “Sorption of Apolar and Polar Organic Contaminants by Waste Tire Rubber and Its Chars in Single- and Bi-solute Systems,” Environmental Pollution, 159, 4, 850–7.
143) Ge, M.; Li, Y.; Liu, L.; Zhou, Z.; Chen, W. 2011, “Bi2O3-Bi2WO6 Composite Microspheres: Hydrothermal Synthesis and Photocatalytic Performances,” Journal of Physical Chemistry C, 115, 13, 5220–5225.
144) Ji, L.; Chen, W.; Bi, J.; Zheng, S.; Xu, Z.; Zhu, D.; Alvarez, P. 2010, “Adsorption of Tetracycline on Single-walled and Multi-walled Carbon Nanotubes as Affected by Aqueous Solution Chemistry,” Environmental Toxicology and Chemistry, 29, 12, 2713–2719.
145) Yang, W.; Kan, A.; Chen, W.; Tomson, M. 2010, “pH-Dependent Effect of Zinc on Arsenic Adsorption to Magnetite Nanoparticles,” Water Research, 44, 19, 5693–5701.
146) Wang, L.; Zhu, D.; Duan, L.; Chen, W. 2010, “Adsorption of Single-Ringed N- and S-Heterocyclic aromatics on Carbon Nanotubes,” Carbon, 48, 13, 3906–3915.
147) Qi, Y.; Chen, W. 2010, “Comparison of Earthworm Bioaccumulation between Readily Desorbable and Desorption-Resistant Naphthalene: Implications for Biouptake Routes,” Environmental Science & Technology, 44, 1, 323–328.
148) Zhang, D.; Zhu, D.; Chen, W. 2010, Response to Comment on “Sorption of Nitroaromatics to Soils: Comparison of the Importance of Soil Organic Matter versus Clay,” Environmental Toxicology and Chemistry, 29, 5, 1022–1024.
149) Zhang, Z.; Li, M.; Chen, W.; Zhu, S.; Liu, N.; Zhu, L. 2010, “Immobilization of Lead and Cadmium from Aqueous Solution and Contaminated Sediment Using Nano-Hydroxyapatite,” Environmental Pollution, 158, 2, 514-519.
150) Yu, J.; Berlin, J.; Lu, W.; Zhang, L.; Kan, A.; Zhang, P.; Walsh, E.; Work, S.; Chen, W.; Tour, J.; Wong, M.; Tomson M. 2010, "Transport Study of Nanoparticles for Oilfield Application,” SPE Paper No. 131158-MS, Paper of SPE International Conference on Oilfield Scale, Aberdeen, UK, 26–27 May 2010 (EI).
151) Chen, W.; Duan, L.; Wang, L.; Zhu, D. 2009, Response to Comment on “Adsorption of Hydroxyl- and Amino-Substituted Aromatics to Carbon Nanotubes,” Environmental Science & Technology, 43, 9, 3400–3401.
152) Zhang, D.; Zhu, D.; Chen, W. 2009, “Sorption of Nitroaromatics to Soils: Comparison of the Importance of Soil Organic Matter versus Clay,” Environmental Toxicology and Chemistry, 28, 7, 1447-1454.
153) Chen, W.; Hou, L.; Luo, X.; Zhu, L. 2009, “Effects of Chemical Oxidation on Sorption and Desorption of PAHs in Typical Chinese Soils,” Environmental Pollution, 157, 1894–1903.
154) Yang, W.; Zhang, J.; Zhang, C.; Zhu, L.; Chen, W. 2009, “Sorption and Resistant Desorption of Atrazine in Typical Chinese Soils,” Journal of Environmental Quality, 38, 1, 171-179.
155) Ji, L.; Chen, W.; Zheng, S.; Xu, Z.; Zhu, D. 2009, “Adsorption of Sulfonamide Antibiotics to Multi-Walled Carbon Nanotubes,” Langmuir, 25, 19, 11608–11613.
156) Ji, L.; Chen, W.; Duan, L.; Zhu, D. 2009, “Mechanisms for Strong Adsorption of Tetracycline to Carbon Nanotubes: A Comparative Study Using Activated Carbon and Graphite as Adsorbents,” Environmental Science & Technology, 43, 7, 2322–2327.
157) Chen, W.; Zhu, D.; Xing, B. 2009, “Chapter 9: Sorption and Sequestration of Organic Contaminants in Soils and Sediments,” in Natural Organic Matter and Its Significance in the Environment, Part II: Interactions between NOM and Contaminants, Science Press, Beijing, 213-236.
158) Chen, W.; Duan, L.; Wang, L.; Zhu, D. 2008, “Adsorption of Hydroxyl- and Amino-Substituted Aromatics to Carbon Nanotubes,” Environmental Science & Technology, 42, 18, 6862-6868.
159) Chen, J.; Chen, W.; Zhu, D. 2008, “Adsorption of Nonionic Aromatic Compounds to Single-Walled Carbon Nanotubes: Effects of Aqueous Solution Chemistry,” Environmental Science & Technology, 42, 19, 7225-7230.
160) Chen, W.; Cong, L.; Hu, H.; Zhang, P.; Li, J.; Feng, Z.; Kan, A.; Tomson, M. 2008, “Release of Adsorbed Polycyclic Aromatic Hydrocarbons under Cosolvent Treatment: Implications for Availability and Fate,” Environmental Toxicology and Chemistry, 27, 1, 112-118.
161) Yang, W.; Duan, L.; Zhang, N.; Zhang, C.; Shipley, H.; Kan, A.; Tomson, M.; Chen, W. 2008, “Resistant Desorption of Hydrophobic Organic Contaminants in Typical Chinese Soils: Implication for Long-Term Fate and Soil Quality Standards,” Environmental Toxicology and Chemistry, 27, 1, 235-242.
162) Duan, L.; Zhang, N.; Wang, Y.; Zhang, C.; Zhu, L.; Chen, W. 2008, “Release of Hexachlorocyclohexanes from Historically and Freshly Contaminated Soils in China: Implications for Fate and Regulation,” Environmental Pollution, 156, 753-759.
163) Liu, L.; Liu, H.; Zhao, Y.; Wang, Y.; Duan, Y.; Gao, G.; Ge, M.; Chen, W. 2008, “Directed Synthesis of Hierarchical Nano-Structured TiO2 Catalysts and Their Morphology-Dependent Photocatalysis for Phenol Degradation,” Environmental Science & Technology, 42, 7, 2342-2348.
164) Yang, W.; Kan, A.T.; Chen, W.; Tomson, M.B. 2008, “Adsorption and desorption of arsenic on nano-magnetite,” Abstracts of Papers of the American Chemical Society, 235, 7-ENVR Part 1.
165) Chen, W.; Duan L.; Zhu, D. 2007, “Adsorption of Polar and Nonpolar Organic Chemicals to Carbon Nanotubes,” Environmental Science & Technology, 41, 24, 8295-8300.
166) Beckles, D.; Chen, W.; Hughes, J. 2007, “Bioavailability of PAHs Sequestered in Sediment: Microbial Study and Model Prediction,” Environmental Toxicology and Chemistry, 26, 5, 878-883.
167) Zhu, X.; Zhu, L.; Li, Y.; Duan, Z.; Chen, W.; Alvarez, P. 2007, “Developmental Toxicity in Zebrafish (danio rerio) Embryos after Exposure to Manufactured Nanomaterials: Buckminsterfullerene Aggregates (nC60) and Fullerol,” Environmental Toxicology and Chemistry, 26, 5, 976-979.
168) Zhao, H.; Li, Y.; Chen, W.; Cai, B. 2007, “A Novel Salicylaldehyde Dehydrogenase-NahV Involved in Catabolism of Naphthalene from Pseudomonas Putida ND6,” Chinese Science Bulletin, 52, 14, 1942-1948.
169) Chen, W.; Lakshmanan, K.; Kan, A.T.; Tomson, M.B. 2004, “A Program for Evaluating Dual-Equilibrium Desorption Effect on Remediation,” Ground Water, 42, 620-624.
170) Chen, W.; Cong, L.; Kan, A.T.; Tomson, M.B. 2004, “A Rapid Approach to Predicting Bioavailable Fraction of Adsorbed Organic Contaminants,” in Remediation of Chlorinated and Recalcitrant Compounds, Battelle Press, Columbus, Ohio.
171) Chen, W.; Cooley, A.I.; McDonnell, T. 2004, “Calculating Favorable Risk-Based Cleanup Standards Using Non-Ideal Sorption Theory,” in Remediation of Chlorinated and Recalcitrant Compounds, Battelle Press, Columbus, Ohio.
172) Chen, W.; Lakshmanan, K.; Kan, A.T.; Tomson, M.B. 2003, “Impact of Dual-Equilibrium Desorption on Soil/Groundwater Remediation: a Decision-Support Model,” in In Situ and On-Site Bioremediation, Battelle Press, Columbus, Ohio.
173) Chen, W.; Kan, A.T.; Newell, C.J.; Moore, E.M.; Tomson, M.B. 2002, “More Realistic Soil Cleanup Standards with Dual-Equilibrium Desorption,” Ground Water, 40, 153-164.
174) Chen, W.; Kan, A.T.; Newell, C.J.; Tomson, M.B. 2002, “More Realistic Soil Cleanup Standards Using Dual-Equilibrium Desorption Model” in Remediation of Chlorinated and Recalcitrant Compounds, Battelle Press, Columbus, Ohio.
175) Chen, W.; Kan, A.T.; Tomson, M.B. 2001, “Modeling Irreversible Sorption of Hydrophobic Organic Contaminants in Natural Sediments,” in Persistent, Bioaccumulative, Toxic Chemicals I, Fate and Exposure, American Chemical Society.
176) Kan, A.T.; Chen, W.; Tomson, M.B. 2001, “Resistant Desorption Kinetics of Chlorinated Organic Compounds from Contaminated Soil and Sediment,” in Persistent, Bioaccumulative, Toxic Chemicals I, Fate and Exposure, American Chemical Society.
177) Chen, W.; Kan, A.T.; Tomson, M.B. 2000, Response to Comment on “Irreversible Adsorption of Chlorinated Benzenes to Natural Sediments – Implication for Sediment Quality Criteria,” Environmental Science & Technology, 34, 4250-4251.
178) Chen, W.; Kan, A.T.; Tomson, M.B. 2000, “Irreversible Adsorption of Chlorinated Benzenes to Natural Sediments – Implication for Sediment Quality Criteria,” Environmental Science & Technology, 34, 385-392.
179) Chen, W.; Kan, A.T.; Fu, G.; Tomson, M.B. 2000, “Factors Affecting the Release of Hydrophobic Organic Contaminants from Natural Sediments,” Environmental Toxicology and Chemistry, 19, 2401-2408.
180) Chen, W.; Kan, A.T.; Tomson, M.B. 2000, “Impact of Irreversible Sorption on Bioavailability and Risk Assessment,” in Remediation of Chlorinated and Recalcitrant Compounds, C2-1, Risk, Regulatory, and Monitoring Considerations, Battelle Press, Columbus, Ohio.
181) Chen, W.; Kan, A.T.; Tomson, M.B. 2000, “Impact of Irreversible Sorption on Bioavailability, Risk Assessment, and Site Remediation” in 73rd Annual Conference & Exposition on Water Quality and Wastewater Treatment Proceedings, Water Environment Federation.
182) Kan, A.T.; Chen, W.; Tomson, M.B. 2000, “Desorption Kinetics of Neutral Hydrophobic Organic Compounds from a Field Contaminated Sediment,” Environmental Pollution, 108, 81-89.
183) Chen, W.; Kan, A.T.; Fu, G.; Vignona, L.C.; Tomson, M.B. 1999, “Adsorption-Desorption Behaviors of Hydrophobic Organic Compounds in Sediments of Lake Charles, Louisiana, USA,” Environmental Toxicology and Chemistry, 18, 1610-1616.
184) Kan, A.T.; Tomson, M.B.; Chen, W.; Hughes, J.; Reible, D. 1999, “Protocol for Assessment of Biological Available Pollutant Concentration in Soil,” Abstracts of Papers of the American Chemical Society, 218, 79-ENVR Part 1.
185) Tomson, M.B.; Kan, A.T.; Beckles, D.; Friedffeld, S.; Chen, W.; Hughes, J.; Reible, D. 1999, “Biological Response and Availability of Desorption Resistant Organic Pollutants,” Abstracts of Papers of the American Chemical Society, 218, 78-ENVR Part 1.
186) Chen, W.; Kan, A.T.; Tomson, M.B. 1999, “Factors Affecting the Resistant Release of Hydrophobic Organic Contaminants from Natural Sediments,” Abstracts of Papers of the American Chemical Society, 217, 003-ENVR Part 1.
187) Chen, W.; Kan, A.T.; Tomson, M.B. 1999, “Modeling of Irreversible Sorption of Chlorinated Benzenes in Natural Sediments,” Abstracts of Papers of the American Chemical Society, 217, 190-ENVR Part 1.
188) Tomson, M.B.; Vignona, L.; Chen, W.; Kan, A.T. 1999, “The Impact of Target Clean-Up Levels on Remediation,” Abstracts of Papers of the American Chemical Society, 217, 006-ENVR Part 1.
189) Chen, W. 1999, “Impact of Irreversible Sorption on Sediment Quality,” Ph.D. thesis, Rice University, Houston, Texas.
190) Kan, A.T.; Fu, G.; Hunter, M.; Chen, W.; Ward, C.H.; Tomson, M.B. 1998, “Irreversible Sorption of Neutral Hydrocarbons to Sediments: Experimental Observations and Model Predictions,” Environmental Science & Technology, 32, 892-902.
191) Chen, W.; Kan, A.T.; Tomson, M.B. 1997, “Sorption and Desorption of Hydrocarbons to and from Historically Contaminated Lake Charles Sediments,” Abstracts of Papers of the American Chemical Society, 214, 91-ENVR Part 1.
192) Tomson, M.B.; Kan, A.T.; Fu, G.; Chen, W. 1997, “Irreversible Adsorption and Fate of Contaminants in Sediments and Soils” Abstracts of Papers of the American Chemical Society, 214, 92-ENVR Part 1.
193) Chen, W. 1997, “Sorption and Desorption of Hydrophobic Organic Compounds to and from Historically Contaminated Lake Charles Sediments,” M.S. thesis, Rice University, Houston, Texas.
194) Chen, W.; Kan, A.T.; Tomson, M.B. 1996, “The Influences of Various Factors on the Adsorption-Desorption Behaviors of Hydrophobic Organic Compounds in Sediments of Lake Charles, LA,” Abstracts of Papers of the American Chemical Society, 211, 52-ENVR Part 1.
195) Zhu, T.; Chen, W. 1994, “Methodology of Environmental Impact Assessment for Regional Development,” Journal of Environmental Science, 6 (4), 457-463.
196) 刘振海,张展华,袁语欣,朱盼盼,陈威,张彤*. 2023, “矿物超细颗粒的形成机制、结构特征及其环境行为和效应”, 环境科学, in press.
197) 刘雅琪,张展华,常青,张彤*,陈威. 2023, “铁锰基纳米材料在土壤-地下水污染修复中的应用”,中国科学:化学,accepted。
198) 朱盼盼,张展华,张彤*,陈威. 2022, “碳点荧光传感器的构建及其在环境污染分析中的应用”,中国科学:化学,accepted。
199) 赵梦婷,秦艺源,邱 野,祝美玲,陈 威. 2022,“微塑料的环境老化机制及效应研究进展”,环境化学,in press。
200) 李旭光;杜婷婷;刘金;刘新蕾;马朋坤;戚豫;陈威,2017,《人工碳纳米材料的环境转化及其效应》,化学进展,29(9): 1021-1029。
201) 王秋泉,牛军峰,闫兵,刘猛,刘倩,刘思金,刘景富,全燮,陈威,张礼知,林璋,潘炳才,2017,“纳米材料环境化学研究进展”,环境化学前沿,科学出版社,北京,401-450。
202) 庞然,岳芳宁,王希萌,陈威,张承东,2014,“复杂环境条件下富勒烯的微生物毒性效应”,环境化学,33(1), 1-9。
203) 陈威,2011,“纳米技术在地下水污染控制与修复中的应用”,环境化学学科前沿与展望,科学出版社,北京,290-300。
204) 段林,段林,张承东,陈威,2011,“土壤和沉积物中疏水性有机污染物的锁定及其环境效应”,环境化学,30(1),242-251。
205) 齐亚超,张承东,王贺,陈威,2010,“黑碳对土壤和沉积物中菲的吸附解吸行为及生物可利用性的影响”,环境化学,29(5),848-855。
206) 乔俊,陈威,张承东,2010,“添加不同营养助剂对石油污染土壤的生物修复研究”,环境化学,29(1),6-11。
207) 段林,陈威,朱东强,2010,“第7章:碳黑与污染物的相互作用机理”,天然有机质及其在环境中的作用机理,地质出版社,北京,164-181。
208) 齐建超,张承东,乔俊,郭婷,张清敏,陈威,2010,“微生物与有机肥混合剂修复石油污染土壤的研究”,农业环境科学学报,1,66-72。
209) 郭婷,张承东,齐建超,张清敏,乔俊,陈威,2009,“酵母菌—细菌联合修复石油污染土壤研究”,环境科学研究,22(19),1472-1477。
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学校介绍
南开大学是教育部直属重点综合性大学,是敬爱的周恩来总理的母校。新中国成立以来,学校发展始终得到党和国家的亲切关怀。毛泽东主席题写校名、亲临视察;周恩来总理三回母校指导;邓小平同志会见数学大师陈省身,批示成立南开数学研究所;江泽民同志、胡锦涛同志先后视察南开。特别是党的十八大以来,习近平总书记多次对南开的发展给予肯定,并对相关工作回信和勉励,更在百年校庆之际亲临南开视察。
南开大学由严修、张伯苓秉承教育救国理念创办,肇始于1904年,成立于1919年。1937年校园遭侵华日军炸毁,学校南迁。1938年与北京大学、清华大学合组西南联合大学,被誉为“学府北辰”。1946年回津复校并改为国立。
新中国成立后,经历高等教育院系调整,成为文理并重的全国重点大学。改革开放以来,天津对外贸易学院、中国旅游管理干部学院相继并入,经教育部与天津市共建支持,学校发展成为国家“211工程”和“985工程”重点建设的综合性研究型大学。2015年9月,新校区建成启用后,初步形成了八里台校区、津南校区、泰达学院“一校三区”办学格局。2017年9月,入选国家42所世界一流大学建设高校,且为36所A类高校之一。
南开大学坚持“允公允能,日新月异”的校训,弘扬“爱国、敬业、创新、乐群”的传统和“文以治国、理以强国、商以富国”的理念,以“知中国,服务中国”为宗旨,以杰出校友周恩来为楷模,作育英才,繁荣学术,强国兴邦,传承文明,努力建设世界一流大学。
南开大学占地443.12万平方米,其中八里台校区占地121.60万平方米,津南校区占地245.89万平方米,泰达学院占地6.72万平方米。校舍建筑总面积195.19万平方米。按照“独立办学、紧密合作”的原则,与天津大学全面合作办学。
南开大学是国内学科门类齐全的综合性、研究型大学之一。在长期办学过程中,形成了文理并重、基础宽厚、突出应用与创新的办学特色。有专业学院26个,学科门类覆盖文、史、哲、经、管、法、理、工、农、医、教、艺等。
南开大学拥有一支公能兼备、业务精湛、奋发有为、充满活力的师资队伍。有专任教师2202人。其中,博士生导师885人、硕士生导师783人,教授898人、副教授857人。
南开大学具备培养学士、硕士和博士的完整教育体系。有在校学生31418人,其中本科生17005人,硕士研究生10299人,博士研究生4114人。有网络专科学生40230人,网络本科学生73029人。
学校积极构建和发展适应21世纪经济社会发展和人才培养需要的学科体系,有本科专业93个(其中国家级特色专业18个),硕士学位授权一级学科11个,硕士专业学位授权点27个,博士学位授权一级学科31个,不在一级学科覆盖下的二级博士点1个,博士后科研流动站28个。有国家“双一流”建设学科5个,一级学科国家重点学科6个(覆盖35个二级学科),二级学科国家重点学科9个,一级学科天津市重点学科32个,国家级一流本科专业建设点21个,省级一流本科专业建设点2个。有国家重点实验室2个,国家工程研究中心1个,国家地方联合工程研究中心1个,2011协同创新中心3个。教育部重点实验室7个,教育部工程研究中心3个,教育部国际合作联合实验室2个,国家环境保护重点实验室1个,国家人权教育与培训基地1个,教育部人文社会科学重点研究基地6个,省部共建协同创新中心1个,教育部国别和区域研究基地7个(培育基地1个、备案基地6个),示范性国家国际科技合作基地4个。国家级实验教学示范中心5个,国家级虚拟仿真实验教学中心2个,国家虚拟仿真实验教学项目2项,国家基础学科人才培养和科学研究基地9个,国家教材建设重点研究基地1个,国家大学生文化素质教育基地1个,中华传统文化传承基地2个,国家创新人才培养示范基地1个。天津市重点实验室20个,天津市工程技术中心4个,天津市普通高等学校实验教学示范中心14个,天津市普通高等学校实验教学示范中心建设单位1个,天津市国际科技合作基地22个,天津市人文社科重点研究基地9个,天津市高校智库8个,天津市社科实验室5个,天津市爱国主义教育基地1个。
有中国科学院院士11人,中国工程院院士4人,发展中国家科学院院士8人,教育部“长江学者奖励计划”特聘教授44人、青年学者19人,“国家杰出青年科学基金”获得者57人、“国家优秀青年科学基金”获得者39人,国家“万人计划”领军人才27人、青年拔尖人才15人,国家“百千万人才工程”入选者30人,教育部“跨世纪人才基金”获得者21人、“新世纪优秀人才支持计划”入选者158人,国家级有突出贡献的专家22人,国务院学位委员会学科评议组成员16人,国家自然科学基金创新研究群体负责人6人,“国家高技术研究发展计划(863计划)”首席科学家3人,“国家重点基础研究发展计划(973计划)”首席科学家15人,国家重点研发计划项目负责人24人。国家级教学名师奖获得者7人,国家级教学团队9个,教育部“高校青年教师奖”获得者8人。天津市杰出人才8人,天津市“人才发展特殊支持计划”领军人才3人、青年拔尖人才11人、高层次创新创业团队带头人11人,天津市有突出贡献专家7人,天津市杰出津门学者3人,天津市“131”创新人才培养工程第一层次人选63人、创新型人才团队带头人17人,“天津市杰出青年科学基金”获得者40人,天津市级教学名师奖获得者35人,天津市级教学团队18个。
南开大学既是教学中心,又是科研中心,取得了一批国内外公认的优秀成果。2019年,周其林院士领衔完成的“高效手性螺环催化剂的发现”项目获国家自然科学奖一等奖。2007—2018年以第一单位获得国家自然科学二等奖4项,国家科技进步二等奖1项,国家技术发明二等奖1项。获国家教学成果奖46项,国家级精品资源共享课31门,国家级精品视频公开课15门,国家级一流本科课程31门,中国专利优秀奖1项,中国青年科技奖2项,全国百篇优秀博士论文累计入选20篇。2018年以来,南开学者团队以第一完成单位在Science上发表研究论文6篇。
南开大学秉承“知中国,服务中国”的优良传统,立足“四个服务”职责使命,聚焦“一带一路”、京津冀协同发展、雄安新区建设等国家和区域发展战略,积极发挥学科、人才和技术优势,努力为国家和地方经济社会发展服务。习近平新时代中国特色社会主义思想研究院、21世纪马克思主义研究院、亚太经济合作组织研究中心、中国新一代人工智能发展战略研究院、经济与社会发展研究院、滨海开发研究院、人权研究中心、津南研究院、统计研究院、生态文明研究院等研究机构是国家有关部委和地方政府的“智囊团”和“人才库”。学校按照“国家急需,世界一流”的原则,全面对接“创新驱动发展”战略、“中国制造2025”等的实施,积极推动各类协同创新中心和若干高层次交叉科学中心建设,与一批高校、企业、科研院所、政府部门建立了紧密合作关系。
南开大学重视学生德、智、体、美、劳全面发展,构建南开特色的“公能”素质教育体系,探索“课堂教学-校园文化-社会实践”三位一体育人模式。以“注重素质、培养能力、强化基础、拓宽专业、严格管理、保证质量”为教学指导思想,实行弹性学制、学分制、主辅修制、双学位制。注重培育优良校风,大力加强校园文化建设,为学生营造丰富高雅、活泼向上的成长氛围。推进创新创业教育,开办“创业班”,推进“南开大学学生创新创业实践基地”建设,提升学生创新能力,助力学生创业计划落地。大力开展“师生同行”社会实践,搭建师生“受教育、长才干、作贡献”的互动平台。南开毕业生以专业基础扎实、综合素质全面、富于开拓精神和实践能力而受到社会各界青睐。
南开大学有着广泛的国际影响,与320多所国际知名大学和国际学术机构建立了合作与交流关系;有专兼职外国专家400余人,以及来自114个国家和地区的2000余名留学生在校学习;承建了英国格拉斯哥大学孔子学院等8所海外孔子学院;与英国牛津大学、伯明翰大学、韩国SK集团共建国际联合研究中心;与世界经济论坛(达沃斯论坛)、全球大学领导者论坛(GULF)、国际公立大学联盟(IFPU)、国际大学联合会(IAU)、世界工程组织联合会(WFEO)等国际组织保持着密切联系,通过积极参与各类国际组织活动,进一步推动与世界一流大学、机构的实质性、深层次合作。
南开大学先后授予数学家陈省身、物理学家吴大猷、经济学家扬·米尔达尔、美国科学院院士蒋-卡洛·若塔、哈佛大学医学院教授摩斯·居达·福克曼、台湾海基会前董事长江丙坤、美国莱斯大学校长李达伟、世界经济论坛主席克劳斯·施瓦布、新加坡总统陈庆炎、法国宪法委员会主席洛朗·法比尤斯等10位国际著名人士名誉博士称号。诺贝尔奖获得者杨振宁、李政道、罗伯特·蒙代尔、彼得·杜赫提、卡尔·巴里·夏普莱斯、弗农·洛马克斯·史密斯、罗伯特·恩格尔、巴里·詹姆斯·马歇尔、托马斯·萨金特,美国前国务卿基辛格,韩国前总统金大中,欧盟委员会前主席、意大利前总理罗马诺·普罗迪,著名作家金庸等被聘为名誉教授,一批海内外知名学者、著名政治家、企业家任客座教授、兼职教授。
南开大学将深入贯彻落实习近平总书记来校视察重要讲话精神,全面贯彻党的教育方针,坚持社会主义办学方向,落实立德树人根本任务,践行“四个服务”重要使命,加快建设南开品格、中国特色、世界一流大学,培养德智体美劳全面发展的社会主义建设者和接班人,为实现中华民族伟大复兴做出新一代南开人的历史贡献。
(数据截至2020年12月)
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