性别:

学位:博士

职务:

所属学院:市政工程

社会兼职:

E-mail:

个人简介

学习经历 

2007.03-2009.03:博士后,韩国釜山国立大学,环境工程系 

2003.09-2006.12:博士研究生,中国科学技术大学,分析化学 

1998.09-2001.04:硕士研究生,合肥工业大学,水文学及水资源 

1994.09-1998.07:本科,合肥工业大学,给水排水工程 


工作经历 

2012.01-:副教授,合肥工业大学,土木与水利工程学院 

2007.03-2009.03:博士后、研究教授,韩国国立釜山大学,环境工程系 

2004.01-2006.12:讲师,合肥工业大学,土木与水利工程学院 

2001.05-2003.12:助教,合肥工业大学,土木工程系


社会兼职:

国际水协IWA会员,安徽省水利学会会员

主讲课程:

水质工程学、给排水管网系统、专业英语










研究方向

城镇给水排水技术研究及应用、水污染控制理论与技术研究









主持科研项目

近期科研项目情况:

国家自然科学基金项目(主持):51108148,有机砷对废水生物处理过程和脱氮除磷行为的干预,2012.01-2014.12 

国家自然科学基金项目(主要研究人员):51479046,微观水力条件下给水管网微生物聚集行为解析及数值模拟,2015.01-2018.12 

韩国科学与工程基金(主要研究人员):R01-2008-000-11853-0,基于纳米微生物产电系统的高效污水处理工艺,2008.01-2010.12 

合肥工业大学科学研究发展基金项目(主持):050801F,新型生物技术用于剩余污泥减量化的研究,2005.01-2006.12 










参加科研项目


获得奖励情况


发表科研论文

SCI 期刊论文 

[1]. Liu L, Hu QY, Le Y, Chen GW(陈国炜), Tong ZL, Xu Q, Wang G*. 2017. Chlorination-mediated EPS excretion shapes early-stage biofilm formation in drinking water systems. Process Biochemistry. 55:41-48. 

[2]. Liu L, Liu YY, Lu QQ, Chen GW(陈国炜), Wang G*. 2017. Assessing comprehensive performance of biofilm formation and water quality in drinking water distribution systems. Water Science & Technology: Water Supply. 171: 267-278. 

[3] Chen GW(陈国炜), Ke ZC, Liang TF, Liu L*, Wang G*. 2016. Shewanella oneidensis MR-1-induced FeIII reduction facilitates roxarsone transformation. PLoS ONE 114: e0154017. doi:10.1371/journal.pone.0154017. 

[4] Liu L*, Li X, Xia GY, Jin JL, Chen GW(陈国炜).2016. Spatial fuzzy clustering approach to characterize flood risk in urban storm water drainage systems. Natural Hazards, 83:1469-1483. 

[5]. Zhu N, Liu L, Xu Q, Chen GW*(陈国炜), Wang G*. 2015. Resources availability mediated EPS production regulate microbial cluster formation in activated sludge system. Chemical Engineering Journal. 279:129-135. 

[6]. Liu L, Le Y, Jin JL, Zhou YL, Chen GW*(陈国炜). 2015. Chlorine stress mediates microbial surface attachment in drinking water systems. Applied Microbiology and Biotechnology. 99:2861-2869. 

[7]. Liu H, Wang GQ, Ge J, Liu L, Chen GW*(陈国炜). 2014. Fate of roxarsone during biological nitrogen removal process in wastewater treatment systems. Chemical Engineering Journal. 255:500-505. 

[8]. Chen GW(陈国炜), Zhu N, Tang ZB, Ye P, Hu ZH, Liu L*. 2014. Resource availability shapes microbial motility and mediates early-stage formation of microbial clusters in biological wastewater treatment processes. Applied Microbiology and Biotechnology. 98:1459-1467. 

[9]. Liang TF, Ke ZC, Chen Q, Liu L, Chen GW*(陈国炜). 2014. Degradation of roxarsone in a silt loam soil and its toxicity assessment. Chemosphere. 112:128-133. 

[10]. Hu JL, Tong ZL, Chen GW(陈国炜), Zhan XM, Hu ZH*. 2014. Adsorption of roxarsone by iron hydroxide modified multiwalled carbon nanotubes from aqueous solution and its mechanisms. International Journal of Environmental Science & Technology. 11:785-794. 

[11]. Guo QF, Liu L, Hu ZH, Chen GW*(陈国炜). 2013. Biological phosphorus removal inhibition by roxarsone in batch culture systems. Chemosphere. 92:138-142. 

[12]. Hu JL, Tong ZL, Hu ZH*, Chen GW*(陈国炜), Chen TH. 2012. Adsorption of roxarsone from aqueous solution by multi-walled carbon nanotubes. Journal of Colloid and Interface Science, 377:355-361. 

[13]. Hu ZH*, Liu YL, Chen GW(陈国炜), Gui XY, Chen TH. 2011. Characterization of organic matter degradation during composting of manure-straw mixtures spiked with tetracyclines. Bioresource Technology. 102: 7239-7343. 

[14]. Chen GW(陈国炜), Choi SJ, Cha JH, Lee TH, Kim CW*. 2010. Microbial community dynamics and electron transfer of a biocathode in microbial fuel cells. Korean Journal of Chemical Engineering. 27: 1513-1520. 

[15]. Chen GW(陈国炜), Cha JH, Choi SJ, Lee TH, Kim CW*. 2010. Characterization of an open biocathode microbial fuel cell for electricity generation and effluent polish. Korean Journal of Chemical Engineering. 27: 828-835. 

[16]. Cha JH, Kim CW*, Choi SJ, Chen GW(陈国炜), Lee TH. 2009. Evaluation of microbial fuel cell coupled with aeration chamber and bio-cathode for organic matter and nitrogen removal from synthetic domestic wastewater. Water Science & Technology. 60: 1409-1418. 

[17]. Chen GW(陈国炜), Choi SJ, Lee TH, Lee GY, Cha JH, Kim CW*. 2008. Application of biocathode in microbial fuel cells: cell performance and microbial community. Applied Microbiology and Biotechnology. 79: 379-388. 

[18]. Chen GW(陈国炜), Yu HQ*, Xi PG, Xu DQ. 2008. Modeling the yield of activated sludge in the presence of 2,4-dinitrophenol. Biochemical Engineering Journal. 40: 150-156. 

[19] Chen GW(陈国炜), Yu HQ*, Xi PG. 2007. Influence of 2,4-dinitrophenol on the characteristics of activated sludge in batch reactors. Bioresource Technology. 98: 729-733. 

[20]. Chen GW(陈国炜), Xi PG, Xu DQ, Yu HQ*.2007. Comparison between inhibitor and uncoupler for minimizing excess sludge production of activated sludge process. Frontiers of Environmental Science & Engineering. 2007, 1: 63-66. 

[21]. Chen GW(陈国炜), Yu HQ*, Liu HX, Xu DQ. 2006. Response of activated sludge to the presence of 2,4-dichlorophenol in a batch culture system. Process Biochemistry. 41: 1758-1763. 


会议论文

[1] Liu L, Wang G, Chen GW(陈国炜), Disinfection stress mediated cell motility shapes bacterial surface attachment on drinking water supply pipelines. IWA Specialized Conference. Biofilms in drinking water systems: From treatment to tap. Arosa, Switzerland, 23-26, Aug. 2015 

[2]. Cha JH, Choi SJ, Yu HN, Chen GW(陈国炜), Directly applicable microbial fuel cells into aeration tank for wastewater treatment. Workshop on electrochemically active biofilms. Paris, France. 19-21, Nov. 2008 

[3]. Cha JH, Lee GY, Chen GW(陈国炜), Lee TH, Kim CW. Denitrification at the bio-cathode in the two chambered MFC. The First International Microbial Fuel Cell Symposium. University Park, USA, 27-29, May, 2008. 

[4]. Cha JH, Lee GY, Chen GW(陈国炜), Kim JW, Lee TH, Kim CW. Organics and nitrogen compounds removal and electricity production from wastewater using a microbial fuel cell system. The 11th World Congress on Anaerobic Digestion. Brisbane, Australia. 23-27, Sept. 2007. 


专利授权 

微生物聚集体性能的定量显微成像测定及评价方法 (国家发明专利, ZL201310156922.7)第一发明人.