[1]Feng Wen-Dong, Li Jian, Gao Kai, An Hong-Xiang, Wang Yun-Hai*. A comparative study of spent resin degradation by Fenton and O3-Fenton process. Progress in Nuclear Energy,130:103566,2020. (

[2]Feng Wen-Dong, Li Jian, An Hong-Xiang, Wang Yun-Hai*. Degradation of spent radioactive ion exchange resins and its mechanisms by Fenton process. Journal of Renewable Materials, 8:1283-1293, 2020.

[3]Feng Wen-Dong, Wang Yun-Hai*,  Li Jian, Gao Kai, An Hong-Xiang. Decomposition of spent radioactive ion-exchange resine using photo-Fenton process. Journal of Chemical Technology and Biotechnology, 95:2522-2529, 2020.

[4]Pu Kai-Bo, Lu Chuan-Xu, Zhang Kai, Zhang He, Chen Qing-Yun, Wang Yun-Hai*. In situ synthesis of polypyrrole on graphite felt as bio-anode to enhance the start-up performance of microbial fuel cells. Bioprocess and Biosystem Engineering, 43:429-437, 2020.

[5]Chen Qing-Yun*, Haq U. Sajjad, Xing Zhong-Hang, Wang Yun-Hai. Temperature effect on green-synthesized Co3O4 nanoparticles as photocatalyst for overall water splitting. Journal of Photonics for Energy. 10(4):042006, 2020. (

[6]Wenfang Cai, Fei Long, Yunhai Wang, Hong Liu and Kun Guo.Enhancement of microbiome management by machinelearning for biological wastewater treatment.​​​​​​​ Microbial Biotechnology, 2020. (




[1]Cai W.F., Lesnik K.L., Wade M.J., Heidrich E.S., Wang Y.H., Liu H. Incorporating microbial community data with machine learning techniques to predict feed substrates in microbial fuel cells. Biosensors and Bioelectronics, 133:64-71, 2019.
[2]Wang C., Du D., Song M., Wang Y., Li F. A high-power Na3V2(PO4)3-Bi sodium-ion full battery in a wide temperature range. Advanced Energy Materials, 9:1900022-1900028,2019.

[3]Pu K.B., Lu C.X, Zhang K., Zhang H., Chen Q.Y., Wang Y.H. In situ synthesis of polypyrrole on graphite felt as bio-anode to enhance the start-up performance of microbial fuel cells. Bioprocess and Biosystem Engineering.

[4]Fang X.W., Wang L.L., Cai W.F., Jing D.W., Chen Q.Y., Wang Y.H. Simultaneous production of electricity and hydrogen from methanol solution with a new electrochemical technology. International Journal of Hydrogen Energy, 44:15766-15770, 2018
[5]Liu X.H., Xing Z.H., Chen Q.Y., Wang Y.H. Multifunctional photocatalytic fuel cell for simultaneous removal of organic pollutant and chromium(VI) accompanied with electricity production. Chemosphere, 237:124457-124464, 2019.
[1]Pu K.B., Ma Q., Cai W.F., Chen Q.Y., Wang Y.H.*, Li F.J. Polypyrrole modified stainless steel as high performanceanode of microbial fuel cell. Biochemical Engineering Journal, 132:255-261, 2018
[2]Cai W.F., Geng J.F., Pu K.B., Ma Q., Jing D.W., Wang Y.H.*, Chen Q.Y., Liu H. Investigation of a two-dimensional model on microbial fuel cell with different biofilm porosities and external resistances. Chemical Engineering Journal, 333:572-582, 2018.
[3] Q. Ma, K.B. Pu, W.F. Cai, Y.H. Wang*, Q.Y. Chen, F.J. Li. Characteristics of poly(3,4-ethylenedioxythiophene) modified stainless steel as anode in air-cathode microbial fuel cells. Industrial &Engineering Chemistry Research, 57, 6633-6638, 2018. (Cover article)
[4] X.W. Fang, L.L. Wang, W.F. Cai, D.W. Jing*, Q.Y. Chen, Y.H. Wang*. Simultaneous production of electricity and hydrogen from methanol solution with a new electrochemical technology. International Journal of Hydrogen Energy,
[5]Qingyun Chen*, Jing Yang, Hui Jin, Yunhai Wang. Simultaneous treatment of copper wastewater and biomass waste in supercritical water. The Journal of Supercritical Fluids, 138:143-146,2018.
[6]Qingyun Chen*, Fan Du, Cheng Cheng, Xiaohe Liu, Yunhai Wang. Enhancing hydrogen evolution of g-C3N4 with nitrogen vacancies by ethanol thermal treatment. Journal of Nanoparticles Research, 20:95-103, 2018.
[1]Cai W.F., Pu K.B., Ma Q., Wang Y.H.*. Insight into the fabrication and perspective of dendritic Ag nanostructures. Journal of Experimental Nanosciene, 12(1):319-337, 2017.
[2]Chen Q.Y.*, Zhang K., Liu J.S., Wang Y.H. Hydrogen and electricity reduction in a light-assisted microbial photoelectrochemical cell with CaFe2O4 photocathode. Journal of Photonics for Energy, 7(2): 026501-7, 2017.
[3]Liu X. H., Du F., Chen Q.Y.*, Wang Y.H. An effective self-driven PFC-PEC hybrid system for hydrogen generation from organic substance. Electrochimica Acta, 245: 379–385, 2017.
[4]Du F., Chen Q.Y.*, Wang Y.H. Heterostructure CuO/Cu2O as a highly efficient photocathode for photoelectrochemical water reduction. Journal of Physics and Chemistry of Solids, 104:139-144, 2017.
[1]Cai W.F., Geng D.L., Wang Y.H.* Assesment of cathode materials for Ni(II) reduction in microbial electrolysis cell. RSC Advances, 6:31732-31738, 2016.
[2]Xu M.X., Wang Y. H.*, Geng J.F., Jing D.W. Photodecomposition of NOx on Ag/TiO2 composite catalysts in a gas phase reactor. Chemical Engineering Journal, 307:181-188, 2017.
[1]Cai W.F., Fang X.W., Xu M.X., Liu X.H., Wang Y.H.* Sequential recovery of copper and nickel from wastewater without net-energy input. Water Science &Technology, 71(5):754-760, 2015.
[2]Chen Q.Y., Fu R., Fang X.W., Cai W.F., Wang Y.H.* Cheng S.A.,Cr-methanol fuel cell for efficient Cr(VI) removal and high power production. Applied Energy, 138:31-35, 2015.
[3]Chen Q.Y.*, Liu J.S., Liu Y., Wang Y.H. Influence of operating parameters on the bio-photoelectrochemical cell for hydrogen and electricity production. Environmental Progress & Sustainable Energy, 34(6):1796-1800, 2015
[1]Liu Y.P., Wang Y.H.*, Wang B.S., Chen Q.Y. Effect of anolyte pH and cathode Pt loading on electricity and hydrogen co-production performance of the bio-electrochemical system. International Journal of Hydrogen Energy. 39(26):14191-14195, 2014.
[2]Chen Q.Y.*, Liu L., Wang Y.H. Preparation and Characterization of Novel Fe2O3-Flaky Coated Carbon Fiber by Electrospinning and Hydrothermal Methods. Advances in Condensed Matter Physics.2014 Jun
[1] Wang Yun-Hai*, Wang Bai-Shi, Pan Bin, Chen Qing-Yun, Yan Wei. Electricity production from a bio-electrochemical cell for silver recovery in alkaline media. Applied Energy. 112:1337-1341, 2013.
[2] Li Guo, Wang Yun-Hai*, Chen Qing-Yun. Influence of fluoride-doped tin oxide interlayer on Ni-Sb-SnO2/Ti electrodes. Journal of Solid State Electrochemistry 17(5): 1303-1309, 2013.
[3] Wang Yun-Hai*, Kuang Jun-Yao. Electrochemical treatment of oilfield produced wastewater on Ni-Sb-SnO2/Ti electrodes. Journal of Advanced Oxidation Technologies 16(2):280-285, 2013.
[4] Wang Yun-Hai*, Li Guo, Zhou Zhe, Chen Qing-Yun, Geng Xin, Yan Wei, Effects of drying periods on antimony doped tin dioxide coated titanium electrode. Journal of Solid State Electrochemistry 17(7):1985-1989, 2013.
[5] Wang Yun-Hai, Zhao Jing-Lian*,Liang Yong. Degradation kinetics of phenol by a titanium dioxide photocatalyst coupled with a magnetic field. Reaction Kinetics Mechanisms and Catalysis 109(1):273-283, 2013.
[6] Wang Yun-Hai, Zhao Jing-Lian*,Liang Yong. Photocatalytic degradation of phenol in aqueous solution by titanium dioxide coupled with magnetic field. Journal of Advanced Oxidation Technologies 16(1):173-178, 2013.
[7]Wang Yun-Hai*, Wang Bai-Shi, Liu Ya-Peng, Chen Qing-Yun. Electricity and hydrogen co-production from a bio-electrochemical cell with acetate substrate. International Journal of Hydrogen Energy 38:6600-6606, 2013.
[8]Wang Yun-Hai*, Chen Qing-Yun. Anodic materials for electrocatalytic ozone generation. International Journal of Electrochemistry 2013:1-7, 2013.
[9]Cheng Shao-An*, Wang Bai-Shi, Wang Yun-Hai*. Increasing efficiency of microbial fuel cells for collaborative treatment of copper and organic wastewater by designing reactor and selecting operating parameters. Bioresource Technology. 147:332-337, 2013.
[10]Wang Yun-Hai*, Liang Yong-Rong, Li Guo. Silver co-doping effect on the antimony doped tin dioxide electrode. Advanced Materials Research. 734-737:2382-2385, 2013.
[11]Wang Yun-Hai*, Nie Zi-Zhou, Liang Yong-Rong. Characterization of nickel-antimony doped tin oxide electrodes prepared via sol-gel dip-coating method. Advanced Materials Research. 734-737:2155-2158, 2013.
[12]陈庆云*,王云海. 微生物燃料电池阴极功能的研究进展. 化工进展,2013,32(10):1-10.
[13]Chen Qing-Yun*, Liu Jian-Shan, Liu Ya, Wang Yun-Hai. Hydrogen production on TiO2 nanorod arrays cathode coupling with bio-anode with additional electricity generation. Journal of Power Sources. 238:345-349, 2013.
[14]Chen Qing-Yun*, Xue Chao, Li Xiang-Lin, Wang Yun-Hai. Surfactants effect on the photoactivity of Fe-doped TiO2. Materials Science Forum. 743-744:367-371, 2013.
[15]Chen Qing-Yun*, Gu Xin, Wang Yun-Hai, Jing Deng-Wei. Synthesis of nanocrystalline yttrium iron oxides and their activity for photocatalytic hydrogen evolution. Science of Advanced Materials. 5(8):1117-1122, 2013.
[16]Chen Qingyun*, Suo Cheng, Zhang Shu, Wang Yun-Hai. Effect of PdS on photocatalytic hydrogen evolution of nanostructured CdS under visible light irradiation.International Journal of Photoenergy. 2013:1-5,2013.
[1]Zhang Shu, Chen Qing-Yun*, Wang Yun-Hai, Guo Lie-Jin*. Synthesis and photoactivity of CdS photocatalysts modified by polypyrrole. International Journal of Hydrogen Energy 37: 13030-13036, 2012.
[2]Zhang Shu, Chen Qing-Yun*, Jing Deng-Wei, Wang Yun-Hai, Guo Lie-Jin. Visible photoactivity and antiphotocorrosion performance of PdS-CdS photocatalysts modified by polyaniline. International Journal of Hydrogen Energy 37:791-796, 2012.
[3]Fu W.N., Wang Y.H., He C, Zhao J L*. Photocatalytic degradation of acephate on ZnFe2O4-TiO2 photocatalyst under visible light irradiation. Journal of Advanced Oxidation Technologies 15(1):177-182, 2012.
[1]王文婷,王云海*. 膨润土改良土壤技术的研究进展. 环境科技24(1):66-72,2011
[2]王文婷,王云海*,赵景联. 有机膨润土在石油污染土壤生物修复中的应用. 化工进展,30:571-574,2011.
[1]陈庆云, 周苗, 王云海. 钒酸铋光催化剂的制备及其还原二氧化碳的研究.化工进展,29(SI):443-445, 2010.
[2]Chen Qing-Yun*, Shi Dong-Dong, Zhang Yuan-Jun, Wang Yun-Hai. Phenol degradation on novel nickel-antimony doped tin dioxide electrode.Water Science and Technology. 62(9):2090-2095,2010.
[1]王云海*,况均耀,周喆,陈庆云. 电化学催化氧化和电吸附脱盐技术处理采油废水. 化工进展, 28:117-120,2009.
[2]Cui Y. H., Wang Y. H.Wang B., Zhou H. H., Chan K. Y. and Li X. Y., Electrochemical generation of ozone in a membrane electrode assembly cell with convective flow, Journal of the Electrochemical Society, 156(4):E75-E80, 2009
Before 2008
[1]Wang Y. H., Chan K. Y., Li X. Y. and So S. K., Electrochemical degradation of 4-chlorophenol on nickel-antimony doped tin oxide electrode, Chemosphere, 65:1087, 2006.
[2]Wang Y. H.,Cheng S. A. and Chan K. Y., Synthesis of ozone from air via a polymer-electrolyte-membrane cell with a doped tin oxide anode, Green Chemistry, 8 (6): 568, 2006.

[3]Wang Y. H., Cheng S. A., Chan K. Y.and Li X. Y., Electrolytic generation of ozone on antimony and nickel doped tin oxide electrode, Journalofthe Electrochemical Society, 152 (11): D197, 2005.



[1]Wang Y.H., Chen Q Y, Li G and Li X L. Anodic materials with high energy efficiency for electrochemical oxidation of toxic organics in waste water. A chapter in Industrial Waste(ISBN:979-953-307-543-2) Edited by Show K.Y., Intech Publishing, Croatia, 2012.

[2]王云海, 杨树成, 梁继东, 张瑜. 水污染控制工程试验(ISBN:978-7-5605-5376-4). 西安交通大学出版社, 西安, 2013(主编).


[3]王云海, 陈庆云赵景联. 环境有机化学(ISBN:978-7-5605-7148-5). 西安交通大学出版社, 西安, 2015. (主编)


[4]Pu K.B., Bai J.R., Chen Q.Y., Wang Y.H. Modified stainless steel as anode materials in bioelectrochemical system, A chapter in Novel Catalyst Materials for Bioelectrochemical Systems: Fundamentals and Applications., edited by Singh L, Mahapatra DM &Liu H. American Chemical Society: Washington DC 2020.