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副教授


邓欢,19824月生于南京,博士,副教授,硕士生导师5C679


联系方式

电子邮箱:hdeng@njnu.edu.cn


教育背景

2007.09-2011.01 中国科学院生态环境研究中心,环境科学专业,博士

2005.10-2006.01 英国James Hutton研究所,分子生态学研究

2004.09-2007.07 中国科学院南京土壤研究所,土壤学,硕士

2000.09-2004.06 南京农业大学,生物科学,学士


研究经历

2018.09-2019.09,美国犹他大学化学系,访问学者

2013.03-至今,南京师范大学环境学院,副教授,硕士生导师

2011.03 -2013.01 中国科学院城市环境研究所,生物学专业,博士后


研究方向

土壤产电微生物及其电信号和电能产生技术


主讲课程

环境生物学、环境微生物学

获奖情况

[1] 2017年,入选南师大百人计划青蓝工程

[2] 2016年,南师大优秀教师奖

[3] 2015年,江苏省高校微课教学比赛本科组二等奖


主持科研项目

1、国家自然科学基金面上项目土壤产电信号及其指示土壤重金属污染的微生物机制” (41671250)20171-202012

2、国家自然科学基金青年项目土壤产电信号与土壤微生物功能和回复力的相关性及机理研究” (41301260)20141-201612

3、国家重点研发计划子课题土壤酸化与氮转化互作及其微生物学机制” (2016YFD0200302)20161-202012

4、江苏省自然科学基金面上项目土壤源的生物阴极细菌多样性及电子传递机制”(BK20171476)20177-20206


发表论文、专利及专著

以一作或通讯作者身份发表论文27*通讯作者)

[1] Deng H, Jiang YB, Zhou YW, Shen K, Zhong WH*. 2015. Using electrical signals of microbial fuel cells to detect copper stress on soil microorganisms. European Journal of Soil Science 66:369-377.

[2] Jiang YB, Deng H(共同一作), Sun DM, Zhong WH*. 2015. Electrical signals generated by soil microorganisms in microbial fuel cells respond linearly to soil Cd2+ pollution. Geoderma 255-256:35-41.

[3] Jiang YB, Zhong WH, Han C, Deng H*. 2016. Characterization of electricity generated by soil in microbial fuel cells and the isolation of soil source exoelectrogenic bacteria. Frontiers in Microbiology 7:1776.

[4] Wang J, Deng H*, Wu SS, Deng YC, Liu L, Han C, Jiang YB, Zhong WH. 2019. Assessment of abundance and diversity of exoelectrogenic bacteria in soil under different land use types. Catena. 172:572-580.

[5] Wu SS, Hernándezc M, Deng YC, Han C, Hong X, Xu J, Zhong WH, Deng H*. 2019. The voltage signals of microbial fuel cell based sensors positively correlated with methane emission flux in paddy fields of China. FEMS Microbiology Ecology, 95: fiz018

[6] Zhong WH, Cai LC, Wei ZG, Xue HJ, Han C, Deng H*. 2017. The effects of closed circuit microbial fuel cells on methane emissions from paddy soil vary with straw amount. Catena 154:33-39.

[7] Lu Y, Liu L, Wu SS, Zhong WH, Xu YJ, Deng H*. 2019. Electricity generation from paddy soil for powering an electronic timer and an analysis of active exoelectrogenic bacteria. AMB Express, 9:57.

[8] Wu SS, Deng H*, Han C, Liu L, Zhong WH. 2018. A novel sediment microbial fuel cell based sensor for on-line and in situ monitoring copper shock in water. Electroanalysis 30: 2668-2675.

[9] Deng H, Xue HJ, Zhong WH. 2017. A novel exoelectrogenic bacterium phylogenetically related to clostridium sporogenes isolated from copper contaminated soil. Electroanalysis 29:1294-1300.

[10] Deng H, Wu YC, Zhang F, Huang ZC, Chen Z, Xu HJ, Zhao F*. 2014. Factors affecting the performance of single-chamber soil microbial fuel cells for power generation. Pedosphere 24:330-338.

[11] Deng H, Chen Z, Zhao F*. 2012. Energy from plants and microorganisms progress in plant-microbial fuel cells. ChemSusChem 5:1006-1011.

[12] Deng H*. 2012. Diversity-stability relationship of soil microbial community: What do we not know? Journal of Environmental Sciences 24:1027-1035.

[13] Yin R, Deng H*, Wang HL, Zhang B. 2014. Vegetation type affects soil enzyme activities and microbial functional diversity following re-vegetation of a severely eroded red soil in sub-tropical China. Catena 115:96-103.

[14] Mao TT, Yin R, Deng H*. 2015. Effects of copper on methane emission, methanogens and methanotrophs in the rhizosphere and bulk soil of rice paddy. Catena 133:233-240.

[15] Zhang Y, Deng H*, Xue HJ, Chen XY, Cai C, Deng YC, Zhong WH. 2016. The effects of soil microbial and physiochemical properties on resistance and resilience to copper perturbation across China. Catena 147: 678-685.

[16] Deng H, Zhang B, Yin R, Wang HL, Mitchell SM, Griffiths BS, Daniell TJ*. 2010. Long-term effect of re-vegetation on the microbial community of a severely eroded soil in sub-tropical China. Plant Soil, 328: 447-458.

[17] Deng H, Li XF, Cheng WD, Zhu YG*. 2009. Resistance and resilience of Cu-polluted soil after Cu perturbation, tested by a wide range of soil microbial parameters. FEMS Microbiology Ecology. 70: 293-304.

[18] Deng H, Guo GX, Zhu YG*. 2011. Pyrene effects on methanotroph community and methane oxidation rate, tested by dose-response experiment and resistance and resilience experiment. Journal of Soils and Sediments. 11:312-321.

[19] Deng H, Yu YJ, Sun JE, Zhang JB, Cai ZC, Guo GX, Wen-Hui Zhong*. 2015. Parent materials have stronger effects than land use types on microbial biomass, activity and diversity in red soil in subtropical China. Pedobiologia 58:73-79.

[20] 刘丽,吴少松,杨楚瑶,钟文辉,孟梁,邓欢*. 2019. DH-ISMFC传感器产电信号对连续多次镉污染的响应研究. 环境科学学报,39:2224-2230

[21] 邓欢,薛洪婧,姜允斌,钟文辉*. 2015. 土壤微生物产电技术及其潜在应用研究进展. 环境科学,36:3926-3934.

[22] 姜允斌,薛洪婧,钟文辉,邓欢*. 2014. 土壤微生物产电信号评价芘污染毒性研究. 土壤学报, 51:1332-1341.

[23] 邓欢,王日,许静,沙亚东,李稻云,钟文辉*. 2017. 小型化土壤微生物燃料电池电信号放大电路的设计与运行. 土壤,49:588-591.

[24] 邓欢,许静,郭颖颖,蒋玉颖,魏琳钧,钟文辉*. 2017. 土壤产电信号与线性扫描伏安法联用模拟监测湿地铜污染. 土壤,50(5):942-948

[25] 吴少松,邓欢*,刘丽,王宵宵,孙宁欣,钟文辉. 2018. 沉积物产电信号原位在线监测水体铜污染研究. 环境科学学报,38(6):2454-2461.

[26] 邓欢,蔡旅程,姜允斌,钟文辉*. 2016. 运行微生物燃料电池减排稻田土壤甲烷的研究. 环境科学,37:346-352.

[27] 邓欢,郑志勇,赵峰*. 2015. 希瓦氏菌Shewallena oneidensis MR-1合成硒纳米棒. 微生物学报, 55(8):1074-1078.

授权专利

[1] 发明专利:邓欢, 姜允斌, 钟文辉. 2015. 双室微生物燃料电池电信号检测土壤污染毒性的方法,授权号:ZL201310629437.7

[2] 实用新型专利:邓欢, 吴少松, 洪鑫, 金志薇, 钟文辉. 2017. 一种原位检测湿地底泥产电信号的装置. 授权号:ZL201621364685.9

[3] 实用新型专利:邓欢,许静,郭颖颖,蒋玉颖,魏琳钧,钟文辉. 2017. 一种快速响应水体污染的监测系统. 授权号:ZL201720575719.7

[4] 实用新型专利:邓欢,吴少松,洪鑫,钟文辉. 2017. 一种利用湿地底泥进行原位产电的电池. 授权号:ZL201720575720.X

[5] 实用新型专利:邓欢,刘丽,吴少松,杨楚瑶,吴俊霆,钟文辉. 2018. 一种基于浓差电池的水体重金属污染监测装置. 授权号:ZL201820119063.2

[6] 实用新型专利:邓欢,吴少松,刘丽,鲁雨,钟文辉. 一种利用土壤发电的装置. 授权号:ZL201821580340.6


出版教材、专著

[1] 邓欢,钟文辉.《环境科学与工程实验教程》第4章:环境生物学实验,高等教育出版社,2013.

[2] 朱永官,乔敏,李小方,邓欢.《土壤生物学前沿》第11章:土壤污染的生物诊断与生态风险评价,科学出版社,2014.

[3] 孔晓英,孙冬梅,杨改秀,李颖,邓欢.《生物质能源》第13章:微生物燃料电池,化学工业出版社,2016.

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南京师范大学环境学院,中国南京市文苑路1号 邮编:210023 School of Environment, Nanjing Normal University, No.1, Wenyuan Road, Nanjing, China, 210023 

联系电话:(025)85891455;传真:(025)85891455;Email:envi@njnu.edu.cn