[1]Electrochemical Behavior of Sudan I and Sudan II at Graphene Modified Electrodes. Du, Yi-Nan,Li, Si-Cong,Mi, Xiao-Xia,Zheng, Xiao-Chun,Chen, Gang.

[2]Supercritical CO2 dyeing of ramie fiber with disperse dye. Liu, Zhao-Tie,Zhang, Lili,Liu, Zhongwen,Gao, Ziwei,Dong, Wensheng,Xiong, Heping,Peng, Yuande,Tang, Shouwei.

[3]Naturally derived carbon nanofibers as sustainable electrocatalysts for microbial energy harvesting: A new application of spider silk. Zhou, Lihua,Fu, Peng,Cai, Xixi,Zhou, Shungui,Yuan, Yong.

[4]Glycerol Stabilized NaBH4 Reduction for Preparation Carbon Supported Pt-Ni Alloy Nanoparticles Used as Oxygen-Reduction Electrocatalysts for Microbial Fuel Cells. Wang, Zhong,Wang, Min,Zhao, Jinsheng,Wang, Zhong,Yan, Zhenhua. 2015

[5]Bio-current as an indicator for biogenic Fe(II) generation driven by dissimilatory iron reducing bacteria. Li, Fangbai,Feng, Chunhua,Yue, Xianjun,Wei, Chaohai.

[6]A polypyrrole/anthraquinone-2,6-disulphonic disodium salt (PPy/AQDS)-modified anode to improve performance of microbial fuel cells. Feng, Chunhua,Ma, Le,Mai, Hongjian,Lang, Xuemei,Fan, Shuanshi,Li, Fangbai.

[7]Honeycomb-like hierarchical carbon derived from livestock sewage sludge as oxygen reduction reaction catalysts in microbial fuel cells. Deng, Lifang,Yuan, Haoran,Ruan, Yingying,Chen, Yong,Cai, Xixi,Zhou, Shungui,Yuan, Yong,Deng, Lifang,Yuan, Haoran,Ruan, Yingying.

[8]Arsenite oxidation and removal driven by a bio-electro-Fenton process under neutral pH conditions. Wang, Xiang-Qin,Liu, Chuan-Ping,Yuan, Yong,Li, Fang-bai.

[9]A Simple Method of Improving Microbial Fuel-Cell Performance Based on Polyaniline/Carbon Composite Anodes. Yuan, Yong,Kim, Sunghyun.

[10]Wiring microbial biofilms to the electrode by osmium redox polymer for the performance enhancement of microbial fuel cells. Yuan, Yong,Shin, Hyosul,Kang, Chan,Kim, Sunghyun.

[11]In-situ Cr(VI) reduction with electrogenerated hydrogen peroxide driven by iron-reducing bacteria. Liu, Liang,Yuan, Yong,Li, Fang-bai,Liu, Liang,Feng, Chun-hua,Liu, Liang.

[12]Understanding the role of Fe(III)/Fe(II) couple in mediating reductive transformation of 2-nitrophenol in microbial fuel cells. Li, Fangbai,Liu, Liang,Tong, Hui,Feng, Chunhua,Feng, Chunhua,Liu, Yongye,Yue, Xianjun,Sun, Kewen.

[13]Electricity generation from starch processing wastewater using microbial fuel cell technology. Lu, Na,Zhang, Jin-tao,Ni, Jin-ren,Lu, Na,Zhou, Shun-gui,Zhang, Jin-tao.

[14]Isolation of a Arthrobacter sp T11 that Degrades Cyanobacterial Hepatotoxin Microcystin from the Sediment of a Shallow Hypertrophic Lake. Qu, Jiangqi,Zhang, Qingjing,Zhang, Mo,Xin, Zhiming,Li, Hongwei,Zhang, Nan. 2015

[15]Dynamics of Oxine-Copper in Pears and Soil by High-Performance Liquid Chromatography. Li, Zeng-Mei,Deng, Li-Gang,Zhang, Shu-Qiu,Liang, Jing-Yun,Guo, Chang-Ying,Dong, Yan-Jie,Zhao, Shan-Cang,Li, Zeng-Mei,Deng, Li-Gang,Zhang, Shu-Qiu,Liang, Jing-Yun,Guo, Chang-Ying,Dong, Yan-Jie,Zhao, Shan-Cang,Wang, Yong-Qin. 2016

[16]Dynamics of nematode assemblages and soil function in adjacent restored and degraded soils following disturbance. Liu, Manqiang,Chen, Xiaoyun,Li, Huixin,Hu, Feng,Chen, Xiaoyun,Griffiths, Bryan S.,Huang, Qianru. 2012

[17]Dephosphorylation enhances postmortem degradation of myofibrillar proteins. Li, Zheng,Li, Meng,Du, Manting,Zhang, Dequan,Shen, Qingwu W.. 2018

[18]Effects of Biochar Amendment on Chloropicrin Adsorption and Degradation in Soil. Wang, Qiuxia,Yan, Dongdong,Fang, Wensheng,Mao, Liangang,Li, Yuan,Ouyang, Canbin,Guo, Meixia,Cao, Aocheng,Wang, Dong. 2016

[19]Changes of phospholipase A(2) and C activities during dry-cured duck processing and their relationship with intramuscular phospholipid degradation. Wang, Daoying,Xu, Xinglian,Zhou, Guanghong,Wang, Daoying,Zhang, Muhan,Bian, Huan,Xu, Weimin,Zhu, Yongzhi,Liu, Fang,Geng, Zhiming. 2014

[20]The Effect of Two Types of Biochars on the Efficacy, Emission, Degradation, and Adsorption of the Fumigant Methyl Isothiocyanate. Cao, Aocheng,Yan, Dongdong,Han, Dawei,Huang, Bin,Li, Jun,Liu, Xiaoman,Guo, Meixia,Wang, Qiuxia. 2017