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杨琥 教授


 

杨琥 教授
博士 硕士生导师


 
通讯地址:南京市栖霞区仙林大道163号;邮编:210046
工作单位:南京大学环境学院仙林校区
电 话: 02589681272
邮箱:yanghu@nju.edu.cn



个人简介
主要从事新型高效环境功能材料的研发及应用基础研究。先后主持国家自然科学基金面上项目3项及青年基金1项,江苏省自然科学基金面上项目1项、建设部研发项目1项及企业资助项目若干;至今,已在国内外学术期刊正式发表论文100余篇,大多为SCI及EI收录;申请国家发明专利10余项。2015年10月入选江苏省“六大人才高峰”高层次人才选拔培养对象。2006年12月至2013年12月曾担任中国化学会高分子专业委员会下属全国高聚物表征委员会委员。




*教育经历:
1993.9-1997.7 南京大学,化学化工学院,高分子化学专业,理学学士;
1997.9-2001.7 南京大学,化学化工学院,高分子化学与物理专业,理学博士。 


 
*工作经历:
2001.9-2003.10 南京大学,化学化工学院,讲师;
2003.11-2012.9 南京大学,化学化工学院,副教授;
2004.11-2006.10京都大学,化学研究所,JSPS特别研究员;
2012.10 -2012.12 南京大学,环境学院,副教授;
2013.1-至今 南京大学,环境学院,教授;



*主要研究领域:

  • 新型环境功能材料的研发与应用研究;

1. 绿色高分子絮凝剂材料的研发及絮凝机理研究

2. 高分子复合磁性微球材料的研制及水处理性能研究

3. 农作物废弃物——秸秆材料在水处理中的综合利用

4. 大气雾霾沉降剂的制备与应用研究

  • 水污染控制技术




*主要科研项目:
1. 国家自然科学基金面上项目:“基于双重结构因素的有机高分子絮凝剂絮凝机理研究”(主持,51378250)

2. 国家自然科学基金面上项目:“两性型天然高分子材料结构形态与絮凝机理研究”(主持,51073077)

3. 国家自然科学基金面上项目:“覆盖整个浓度范围的高分子溶液性质浓度依赖性的研究”(主持,20474026)

4. 国家自然科学基金青年项目:“高分子单链附聚体的制备及性质研究”(主持,20204004)

5. 建设部研发项目:“环保高效型城镇饮用水处理剂的开发与应用研究”(与江苏省镇江市自来水公司联合主持,2009-K7-11)

6. 污染控制与资源化研究国家重点实验室开放课题:“壳聚糖磁性复合微球制备技术及污水深度处理原理”(主持,PCRRF11004)



*国家发明专利:

[1] 壳聚糖雾霾沉降剂的制备方法及其应用;杨琥,李海江,蔡涛等. (ZL201410185349.7)

[2] 一种水解接枝型增强阴离子羧甲基纤维素絮凝剂及其制法;杨琥,杨朕,蔡涛等.(ZL201310125012.2)

[3] 一种化学键链接的强阳离子型接枝两性壳聚糖絮凝剂的制备方法;杨琥,杨朕,李海江等.(ZL201310351096.1)

[4] 一种改性成强阳离子型吸附剂的秸秆及其制法;杨琥,张文轩,杨朕等.(ZL201210089264.X)

[5] 接枝型两性壳聚糖絮凝剂的制备方法;杨琥,尚亚波,杨朕等.(ZL201010223727.8)

[6] 一种两性型壳聚糖絮凝剂的制备方法;杨琥,尚亚波,袁博等.(ZL200810124282.0)

[7] 复合絮凝剂及其制备方法;杨琥,尚亚波,卢耀柏等.(ZL200910176551.2)

[8] 改性氢氧化镁阻燃剂和其组成的高抗冲聚苯乙烯复合阻燃材料及其制法;杨琥,周晨刚,杨朕等.(ZL201110098731.0)

[9] 包膜缓释肥料及其制备方法;杨琥,王治流,程镕时等.(ZL02137895.9)

[10] PE/氢氧化镁复合阻燃材料;杨琥,杨朕,蔡军等.(ZL201010204995.5)

[11] 一种改性成两性型吸附剂的秸秆及其制法;杨琥,张文轩,杨朕等.(201210110877.7)

[12] 一种接枝型两性淀粉絮凝剂的制备方法;杨琥,杨朕,袁博等. (201310051573.2)

[13] 一种两性接枝型改性纤维素絮凝剂的制备方法;杨琥,蔡涛,李海江等.(201410077292.9)

[14] 一种木质素-淀粉复合丁苯橡胶材料及其制备方法;杨琥,李海江,李爱民.(201510216524.9)

[15] 一种壳聚糖-接枝氨基酸磁性复合微球、制备及应用;杨琥,严涵,陶雪等.(201510215364.6)

[16] 一种絮凝灭菌双功能接枝型淀粉水处理剂及其制备方法;杨琥,黄牧,李爱民.(201510263660.3)


*近年来主要代表作:

[1] A review on chitosan-based flocculants and their applications in water treatment, Ran Yang, Haijiang Li, Mu Huang, Hu Yang*, Aimin Li, Water Research, 2016, 95, 59-89.

[2] Evaluation of chain architectures and charge properties of various starch-based flocculants for flocculation of humic acid from water, Hu Wu, Zhouzhou Liu, Hu Yang*, Aimin Li, Water Research, 2016, 96, 126-135.

[3] Preparation of dual-function starch-based flocculants for simultaneous removal of turbidity and inhibition of E. coli in water, Mu Huang, Yawen Wang, Jun Cai, Junfeng Bai, Hu Yang*, Aimin Li, Water Research, 2016, 98, 128-137.

[4] Efficient adsorption of both methyl orange and chromium from their aqueous mixtures using a quaternary ammonium salt modified chitosan magnetic composite adsorbent, Kun Li, Pei Li, Jun Cai, Shoujun Xiao, Hu Yang*, Aimin Li, Chemosphere, 2016, 154, 310-318.

[5] Simultaneous removal of acid green 25 and mercury ions from aqueous solutions using glutamine modified chitosan magnetic composite microspheres, Xue Tao, Kun Li, Han Yan, Hu Yang*, Aimin Li, Environmental Pollution, 2016, 209, 21-29.

[6] pH-tunable surface charge of chitosan/graphene oxide composite adsorbent for efficient removal of multiple pollutants from water, Han Yan, Hu Yang*, Aimin Li, Rongshi Cheng, Chemical Engineering Journal, 2016, 284, 1397-1405.

[7] Efficient removal of chlorophenols from water with a magnetic reduced graphene oxide composite, Han Yan, Qing Du, Hu Yang*, Aimin Li, Rongshi Cheng, Science China-chemistry, 2016, 59(3), 350-359.

[8] Influence of the surface structure of graphene oxide on the adsorption of aromatic organic compounds from water, Han Yan, Hu Wu, Kun Li, Yawen Wang, Xue Tao, Hu Yang*, Aimin Li, Rongshi Cheng, ACS Applied Materials & Interfaces, 2015, 7, 6690-6697.

[9] Efficient flocculation of an anionic dye from aqueous solutions using a cellulose-based flocculant, Tao Cai, Haijiang Li, Ran Yang, Yawen Wang, Hu Yang*, Aimin Li, Rongshi Cheng, Cellulose, 2015, 22(2), 1439-1449.

[10] Preparation of chitosan-graft-polyacrylamide magnetic composite microspheres for enhanced and selective removal of Mercury Ions from water, Kun Li, Yawen Wang, Mu Huang, Han Yan, Hu Yang*, Shoujun Xiao, Aimin Li, Journal of Colloid and Interface Science, 2015, 455, 261-270.

[11] Flocculation of both kaolin and hematite suspensions using the starch-based flocculants and their floc properties, Haijiang Li, Tao Cai, Bo Yuan, Ruihua Li, Hu Yang*, Aimin Li, Industrial & Engineering Chemistry Research, 2015, 54, 59-67.

[12] Modeling and optimization of the flocculation processes for removal of cationic and anionic dyes from water by an amphoteric grafting chitosan-based flocculant using response surface methodology, Hu Wu, Ran Yang, Ruihua Li, Chao Long, Hu Yang*, Aimin Li, Environmental Science and Pollution Research, 2015, 22, 13038-13048.

[13] Rapid removal and separation of iron(II) and manganese(II) from micro-polluted water using magnetic graphene oxide, Han Yan, Haijiang Li, Xue Tao, Kun Li, Hu Yang*, Aimin Li, Shoujun Xiao, Rongshi Cheng, ACS Applied Materials & Interfaces, 2014, 6, 9871-9880.

[14] Flocculation of Escherichia coli Using a quaternary ammonium salt grafted carboxymethyl chitosan flocculant, Zhen Yang, Jean-Regis Degorce-Dumas, Hu Yang*, Eric Guibal*, Aimin Li, Rongshi Cheng, Environmental Science & Technology, 2014, 48, 6867-6873.

[15] Effects of the oxidation degree of graphene oxide on the adsorption of methylene blue, Han Yan, Xue Tao, Zhen Yang, Kun Li, Hu Yang*, Aimin Li, Rongshi Cheng, Journal of Hazardous Materials, 2014, 268, 191-198.

[16] Evaluation of a novel chitosan-based flocculant with high flocculation performance, low toxicity and good floc properties, Zhen Yang, Haijiang Li, Han Yan, Hu Wu, Hu Yang*, Qian Wu, Haibo Li, Aimin Li, Rongshi Cheng, Journal of Hazardous Materials, 2014, 276, 480-488.

[17] Synthesis of amphoteric starch-based grafting flocculants for flocculation of both positively and negatively charged colloidal contaminants from water, Zhen Yang, Hu Wu, Bo Yuan, Mu Huang, Hu Yang*, Aimin Li, Junfeng Bai, Rongshi Cheng, Chemical Engineering Journal, 2014, 244, 209-217.

[18] Amphoteric starch-based flocculants can flocculate different contaminants with even opposite surface charges from water through molecular structure control, Zhen Yang, Bo Yuan, Haijiang Li, Youdi Yang, Hu Yang*, Aimin Li, Rongshi Cheng, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2014, 455, 28-35.

[19] Flocculation performance and mechanism of graphene oxide for removal of various contaminants from water, Zhen Yang, Han Yan, Hu Yang*, Haibo Li, Aimin Li, Rongshi Cheng, Water research, 2013, 47(9), 3037-3046.

[20] Flocculation of both anionic and cationic dyes in aqueous solutions by the amphoteric grafting flocculant carboxymethyl chitosan-graft-polyacrylamide; Zhen Yang, Hu Yang*, Ziwen Jiang, Tao Cai, Haijiang Li, Haibo Li, Aimin Li, Rongshi Cheng, Journal of Hazardous Materials, 2013, 254-255, 36-45.

[21] Effect of hydrolysis degree of hydrolyzed polyacrylamide grafted carboxymethyl cellulose on dye removal efficiency, Tao Cai, Zhen Yang,  Haijiang Li, Hu Yang*, Aimin Li, Rongshi Cheng, Cellulose, 2013, 20(5), 2605-2614.

[22] Removal of various cationic dyes from aqueous solutions using a kind of fully biodegradable magnetic composite microsphere, Han Yan, Haijiang Li, Hu Yang*, Aimin Li, Rongshi Cheng, Chemical Engineering Journal, 2013, 223, 402-411.

[23] A new method for calculation of flocculation kinetics combining Smoluchowski model with fractal theory; Zhen Yang, Hu Yang*, Ziwen Jiang, Xin Huang, Haibo Li, Aimin Li, Rongshi Cheng, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2013, 423, 11-19.

[24] Coagulation properties of biodegradable chitosan-CTA coagulants in turbidity removal; Xin Huang, Yabo Shang, Hu Yang*, Yichun Chen, Zhen Yang, Aimin Chen, Yaobo Lu, Yuxiang Jiang, Wei Gu, Xiaozhi Qian, Aimin Li, Rongshi Cheng, Journal of Environmental Engineering-ASCE, 2013, 139(8), 1123-1127.

[25] Evaluation of the flocculation performance of carboxymethyl chitosan-graft-polyacrylamide, an novel amphoteric chemically bonded composite flocculant; Zhen Yang, Bo Yuan, Xin Huang, Junyu Zhou, Jun Cai, Hu Yang*, Aimin Li, Rongshi Cheng, Water Research, 2012, 46(1), 107-114.

[26] Adsorption of anionic dyes from aqueous solutions using chemically modified straw; Wenxuan Zhang, Haijiang Li, Xiaowei Kan, Lei Dong, Han Yan, Ziwen Jiang, Hu Yang*, Aimin Li, Rongshi Cheng, Bioresource Technology, 2012, 117, 40-47.

[27] Effect of surfactant concentration on the complex structure of poly(N-isopropylacrylamide)/sodium n-dodecyl sulfate in aqueous solutions, Jianqiang Chen, Hongjuan Xue, Yefeng Yao, Hu Yang*, Aimin Li, Min Xu, Qun Chen, Rongshi Cheng, Macromolecules, 2012, 45(13), 5524-5529.

[28] Preparation of chitosan/poly(acrylic acid) magnetic composite microspheres and its applications in the removal of copper(II) ions from aqueous solutions; Han Yan, Lingyun Yang, Zhen Yang, Hu Yang*, Aimin Li, Rongshi Cheng, Journal of Hazardous Materials, 2012, 229-230, 371-380.

[29] Efficient removal of both cationic and anionic dyes from aqueous solutions using a novel amphoteric straw-based adsorbent; Wenxuan Zhang, Hu Yang*, Lei Dong, Han Yan, Haijiang Li, Ziwen Jiang, Xiaowei Kan, Aimin Li, Rongshi Cheng, Carbohydrate Polymers, 2012, 90(2), 887-893.

[30] New insight into “polyelectrolyte effect”, Hu Yang, Qiang Zheng*, Rongshi Cheng*, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2012, 407, 1-8.


 
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