个人履历
吴康兵,男,博士,1977年2月生教育及工作背景
1995年9月-1999年6月,兰州大学,理学学士;
1999年9月-2004年9月,武汉大学硕博连读,理学博士;
2004年7月-2005年10月,华中科技大学化学与化工学院讲师;
2005年11月-2010年10月,华中科技大学化学与化工学院副教授;
2010年11月1日起,华中科技大学化学与化工学院教授。
研究方向
电分析化学、纳米电化学、电化学感测器、食品安全分析、环境监测
奖励/荣誉
湖北省杰青(2016年);
湖北省自然科学三等奖(2013年);
入选教育部新世纪优秀人才支持计画(2010年);
湖北省自然科学二等奖(2010年);
华中科技大学青年五四奖章(2006年);
湖北省优秀博士学位论文(2005年);
教学情况
本科生教学:《无机及分析化学》、《分析化学实验》
研究生教学:《现代电分析化学专题》
主持完成和在研课题
国家自然科学基金面上项目:基于MOFs构效调控的高灵敏选择性电化学感测机理与方法研究(2018-2021)
湖北省自然科学基金杰出青年基金:环境电化学感测与监测(2016CFA039),主持。在研
973课题:纳米仿生识别与催化增敏机理和方法研究(项目名称:超灵敏微纳生物化学感测器集成自治系统基础研究,2015CB352100),主持。在研(2015-2020)
国家自然科学基金面上项目:形貌调控纳米金属氧化物增敏机理及超灵敏食品安全分析新方法(21375041),主持。在研(2013-2018)
教育部新世纪优秀人才支持计画:电化学感测与监测(NCET-11-0187),主持。在研
973子课题:COD纳米电化学增敏机理及现场无线网路化监测(项目名称:水环境监测无线网路化微感测器晶片系统基础研究,2009CB320300),主持。已结题。
国家自然科学基金面上项目:电化学/化学调控酚类环境激素纳米感测及现场检测研究(61071052),主持。已结题。
国家自然科学基金青年基金:重金属离子纳米感测及实时检测的新方法研究(20507006),主持。已结题
广东省教育部产学研课题:基于纳米电化学感测技术快速检测玩具中重金属及设备研究(20111158),主持。已结题。
湖北检验检疫局合作课题:分子印迹仿生感测器在食品检测中的套用研究(200910085),主持。已结题。
发表论文
1、研製出COD纳米电化学感测器与线上监测系统,成功用于太湖水体的现场、无线、网路化监测。2、近五年以第一作者或通讯作者发表SCI论文31篇,总发表论文70余篇。SCI他引1000余次,2篇他引超过100次(单篇最高182次)。
近三年来发表的主要论文如下:
1、WangYY, Chen, F, Ye XX, Wu T, Wu KB*, Li CY*. Photoelectrochemical immunosensing of tetrabromobisphenol A based on the enhanced effect of dodecahedral gold nanocrystals/MoS2, nanosheets.Sensors & Actuators B Chemical,245 (2017) 205-212.
2、Ji LD, Zhang YY, Yu SJ, Hu SS, Wu KB*. Morphology-tuned preparation of nanostructured resorcinol-formaldehyde carbonized polymers as highly sensitive electrochemical sensor for amaranth. Journal of Electroanalytical Chemistry,779(2016) 169-175.
3、Ji LD, Wang YY, Wu KB*, Zhang WK*. Simultaneous determination of environmental estrogens: diethylstilbestrol and estradiol using Cu-BTC frameworks-sensitized electrode.Talanta,159(2016) 215-221.
4、Chen XR, Wang YY, Tong JH, Xia SH, Zhou YK*, Wu KB*. Electrochemical sensing platform for tetrabromobisphenol A at pM level based on the synergetic enhancement effects of graphene and dioctadecyldimethylammonium bromide.Analytica Chimica Acta,935(2016) 90-96.
5、Ji LD, Cheng Q, Wu KB*, Yang XF*. Cu-BTC frameworks-based electrochemical sensing platform for rapid and simple determination of Sunset yellow and Tartrazine.Sensors & Actuators B Chemical,231(2016) 12-17.
6、Zhang YY, Yan P, Wan QJ*, Wu KB*, Yang NJ*. Morphology-dependent electrochemistry of FeOOH nanostructures.Electrochemistry Communications,68(2016) 10-14.
7、Li CC, Chen XR, Wu KB*, Yu SJ*. Signal enhancement of cetyltrimethylammonium bromide as a highly-sensitive sensing strategy for tetrabromobisphenol A.Journal of Electroanalytical Chemistry,770(2016) 39-43.
8、Chen XR, Ji LD, Zhou YK*, Wu KB*. Synergetic enhancement of gold nanoparticles and 2-mercaptobenzothiazole as highly-sensitive sensing strategy for tetrabromobisphenol A.Scientific Reports,6(2016) 26044-20653.
9、Zhang YY, Cheng Q, Zheng M, Liu X, Wu KB*.Iron oxyhydroxide nanorods with high electrochemical reactivity as a sensitive and rapid determination platform for 4-chlorophenol.Journal of Hazardous Materials,307(2016) 36-42.
10、Cheng Q, Ji LD, Wu KB*, Zhang WK*. Morphology-dependent electrochemical enhancements of porous carbon as sensitive determination platform for ascorbic acid, dopamine and uric acid. Scientific Reports,6(2016) 22309-22318.
11、Chen XR, Ji LD, Zhou Y, Xia SH, Tong JH, Wu KB*. Electrochemical enhancement of long alkyl-chained surfactants for sensitive determination of tetrabromobisphenol A.Electrochimica Acta,190(2016) 490-494.
12、Wang YY, Liu GS, Hou XD, Huang YN, Li CY*,Wu KB*. Assembling gold nanorods on a poly-cysteine modified glassy carbon electrode strongly enhance the electrochemical reponse to tetrabromobisphenol A.Microchimica Acta,183 (2016) 689-696.
13、Wang J, Chen X, Wu KB*, Zhang M, Huang WS*. Highly‐sensitive electrochemical sensor for Cd and Pb based on the synergistic enhancement of exfoliated graphene nanosheets and bismuth.Electroanalysis,28(2016) 63-68.
14、 Wu C, Cheng Q, Wu KB*. Electrochemical functionalization of N-methyl-2-pyrrolidone-exfoliated graphene nanosheets as highly sensitive analytical platform for phenols.Analytical Chemistry,87(2015) 3294-3299.
15、 Cheng Q, Xia SH, Tong JH, Wu KB*. Highly-sensitive electrochemical sensing platforms for food colourants based on the property-tuning of porous carbon. Analytica Chimica Acta,887(2015) 75-81.
16、 Wang YY, Han M, Liu GS, Hou XD, Huang YN, Wu KB*, Li CY*. Molecularly imprinted electrochemical sensing interface based on in-situ-polymerization of amino-functionalized ionic liquid for specific recognition of bovine serum albumin.Biosensors & Bioelectronics,74 (2015) 792-798.
17、Hu LT, Cheng Q, Chen DC, Ma M, Wu KB*. Liquid-phase exfoliated graphene as highly-sensitive sensor for simultaneous determination of endocrine disruptors: diethylstilbestrol and estradiol. Journal of Hazardous Materials,283(2015) 157-163.
18、Wu C, Tang Y, Wan CD, Liu HY, Wu KB*. Enhanced-oxidation and highly-sensitive detection of acetaminophen, guanine and adenine using NMP-exfoliated graphene nanosheets-modified electrode. Electrochimica Acta,166 (2015) 285-292.
19、Zhang YY, Hu LT, Liu X*, Liu BF, Wu KB*. Highly-sensitive and rapid detection of ponceau 4R and tartrazine in drinks using alumina microfibers-based electrochemical sensor.Food Chemistry,166(2015) 352–357.
20、Chen XR, Zheng M, Zhou YK*, Tong JH , Wu KB*. Electrochemical enhancement of acetylene black film as sensitive sensing platform for toxic tetrabromobisphenol A.Rsc Advances,5(2015) 105837-105843.
21、 Wu C, Cheng Q, Wu KB*, Wu G, Li Q*. Graphene prepared by one-pot solvent exfoliation as a highly sensitive platform for electrochemical sensing.Analytica Chimica Acta,825 (2014) 26-33.
22、 Song XJ, Shi Z, Tan XH , Zhang SH, Liu GS, Wu KB*. One-step solvent exfoliation of graphite to produce a highly-sensitive electrochemical sensor for tartrazine.Sensors & Actuators B Chemical,197(2014) 104-108.
23、 Wu C, Cheng Q, Li LQ, Chen JP, Wu KB*. Synergetic signal amplification of graphene-Fe2O3, hybrid and hexadecyltrimethylammonium bromide as an ultrasensitive detection platform for bisphenol A.Electrochimica Acta,115(2014) 434-439.
