甄广印

[96] Teng Cai, Yizhi Zhang, Na Wang, Zhongyi Zhang, Xueqin Lu, Guangyin Zhen*. Electrochemically active microorganisms sense charge transfer resistance for regulating biofilm electroactivity, spatio-temporal distribution, and catabolic pathway.Chemical Engineering Journal, 2022, 442(Part 2) 136248.

[95] Xuefeng Zhu, Jing Qi, Lei Cheng, Guangyin Zhen, Xueqin Lu, Xuedong Zhang*. Depolymerization and conversion of waste-activated sludge to value-added bioproducts by fungi. Fuel, 2022, 320: 123890.

[94] Teng Cai, Xueqin Lu*, Zhongyi Zhang, Wanjiang Li, Na Wang, Yizhi Zhang, Ruiliang Zhang, Guangyin Zhen**. Spatial distribution and nitrogen metabolism behaviors of anammox biofilms in bioelectrochemical system regulated by continuous/intermittent weak electrical stimulation. Journal of Cleaner Production, 2022, 336: 130486.

[93] Xueqin Lu, Jianhui Wang, Yule Han, Yan Zhou, Yenan Song, Ke Dong, Guangyin Zhen*. Unrevealing the role of in-situ Fe(II)/S₂O₈^2- oxidation in sludge solid-liquid separation and membrane fouling behaviors of membrane bioreactor (MBR). Chemical Engineering Journal, 2022, 434: 134666.

[92] Zhongxiang Zhi, Yang Pan, Xueqin Lu, Jianhui Wang, Guangyin Zhen*. Bioelectrochemical regulation accelerates biomethane production from waste activated sludge: Focusing on operational performance and microbial community. Science of The Total Environment, 2022, 814: 152736.

[91] Zhongyi Zhang, Xueqin Lu, Chengxin Niu, Teng Cai, Na Wang, Yule Han, Ruiliang Zhang, Yenan Song, Guangyin Zhen*. Clarifying catalytic behaviors and electron transfer routes of electroactive biofilm during bioelectroconversion of CO₂ to CH₄. Fuel, 2022,310, Part C, 122450.

[90] Guangyin Zhen, Shaojuan Zheng, Yule Han, Zhongyi Zhang, Xueqin Lu*, Kai-Qin Xu. Semi-continuous anolyte circulation to strengthen CO₂ bioelectromethanosynthesis with complex organic matters as the e^-/H⁺ donor for simultaneous biowaste refinery. Chemical Engineering Journal, Available online 23 October 2021, 133123.

[89] Dilibaierkezi Kudisi, Xueqin Lu*, Chaoting Zheng, Yue Wang, Teng Cai, Wanjiang Li, Lingtan Hu, Ruiliang Zhang, Yizhi Zhang, Guangyin Zhen*. Long-term performance, membrane fouling behaviors and microbial community in a hollow fiber anaerobic membrane bioreactor (HF-AnMBR) treating synthetic treaphthalic acid-containing wastewater.Journal of Hazardous Materials, 2022,424,127458.

[88] Wu, Wenjie; Bai, Liang; Song, Yenan*; Su, Yuanting; Jiang, Kai; Sun, Haitao; Zhen, Guangyin; Shen, Yan; Yuan, Qinghong; Sun, Zhuo*. Defect-Engineered Graphene Films as Ozonation Catalysts for the Devastation of Sulfamethoxazole: Insight into the Active Sites and Oxidation Mechanism. ACS Applied Materials & Interfaces, 2021, 13(44), 52706–52716.

[87] Kavitha S., Yukesh Kannah R., Guangyin Zhen, Gopalakrishnan Kumar, Rajesh Banu J.* Effect of Solubilization on Acidification, Anaerobic Biodegradability, and Economic Feasibility via Ultrasonic–Zerovalent Iron–Acidic pH Pretreatment of Sludge. Energy & Fuels, 2021, 35, 16617–16628.

[86] J. Rajesh Banu, R. Yukesh Kannah, M. Dinesh Kumar, Preethi, S. Kavitha, M. Gunasekaran, Guangyin Zhen, Mukesh Kumar Awasthi, Gopalakrishnan Kumar*. Spent coffee grounds based circular bioeconomy: Technoeconomic and commercialization aspects. Renewable and Sustainable Energy Reviews, 2021, 152, 111721.

[85] Yujie Tan¹, Ruiliang Zhang¹, Xueqin Lu, Chengxin Niu, Guangyin Zhen*, Gopalakrishnan Kumar, Youcai Zhao. Mechanistic insights into promoted dewaterability, drying behaviors and methane-producing potential of waste activated sludge by Fe²⁺-activated persulfate oxidation. Journal of Environmental Management, 2021, 298: 113429.

[84] Ruiliang Zhang, Xueqin Lu*, Yujie Tan, Teng Cai, Yule Han, Dilibaierkezi Kudisi, Chengxin Niu, Zhongyi Zhang, Wanjiang Li, Guangyin Zhen. Disordered mesoporous carbon activated peroxydisulfate pretreatment facilitates disintegration of extracellular polymeric substances and anaerobic bioconversion of waste activated sludge. Bioresource Technology, 2021, 339: 125547.

[83]Xi Qin, Xueqin Lu*, Teng Cai, Chengxin Niu, Yule Han, Zhongyi Zhang, Xuefeng Zhu, Guangyin Zhen*. Magnetite-enhanced bioelectrochemical stimulation for biodegradation and biomethane production of waste activated sludge. Science of the Total Environment, 2021,789: 147859.

[82]Shasha Wang, Yule Han, Xueqin Lu*, Zhongxiang Zhi, Ruiliang Zhang, Teng Cai, Guangyin Zhen*, Zhongyi Zhang, Xi Qin. Microbial mechanism underlying high methane production of coupled alkali-microwave-H₂O₂-oxidation pretreated sewage sludge by in-situ bioelectrochemical regulation. Journal of Cleaner Production, 2021, 305: 127195.

[81] Lianghu Su, Mei Chen, Saier Wang, Rongting Ji, Chenwei Liu, Xueqin Lu, Guangyin Zhen*, Longjiang Zhang**. Fluorescence characteristics of dissolved organic matter during anaerobic digestion of oil crop straw inoculated with rumen liquid. RSC Advances, 2021, 11:14347-14356.

[80] Chengxin Niu, Teng Cai, Xueqin, Lu,Guangyin Zhen*, Yang Pan, Xuan Ren, Xi Qin, Wanjiang Li, Yingxiang Tang, Zhongxiang Zhi. Nano zero-valent iron regulates the enrichment of organics-degrading and hydrogenotrophic microbes to stimulate methane bioconversion of waste activated sludge. Chemical Engineering Journal, 2021, 418: 129511.

[79]Xueqin Lu, Chaoting Zheng, Guangyin Zhen*, Yujie Tan, Yuhan Zhou, Zhongyi Zhang, Chengxin Niu, Wanjiang Li, Dilibaierkezi Kudisi, Yue Wang, Yu-You Li. Roles of colloidal particles and soluble biopolymers in long-term performance and fouling behaviors of submerged anaerobic membrane bioreactor treating methanolic wastewater. Journal of Cleaner Production, 2021, 290: 125816.

[78] Lianghu Su*, Xu Sun, Chenwei Liu, Rongting Ji, Guangyin Zhen, Mei Chen, Longjiang Zhang*. Thermophilic solid-state anaerobic digestion of corn straw, cattle manure and vegetable waste: Effect of temperature, total solid content and C/N ratio. Archaea, Volume 2020, Article ID 8841490, https://doi.org/10.1155/2020/8841490.

[77] Teng Cai, Nan Jiang, Guangyin Zhen, Lijun Meng, JialingSong, Gang Chen, Yanbiao Liu, Manhong Huang*. Simultaneous energy harvest and nitrogen removal using a supercapacitor microbial fuel cell. Environmental Pollution, 2020, 266: 115154.

[76] Wenjie Wu, Yenan Song*, Liang Bai, Zaizhou Chen, Haitao Sun, Guangyin Zhen, Runze Zhan, Yan Shen, Junchao Qian, Qinghong Yuan, and Zhuo Sun*, Graphene Oxide-BiOCl Nanoparticle Composites as Catalysts for Oxidation of Volatile Organic Compounds in Nonthermal Plasmas. ACS Applied Nano Materials,2020, 3:9363−9374,https://dx.doi.org/10.1021/acsanm.0c01994.

[75] Uthirakrishnan Ushani, Xueqin Lu, Jianhui Wang, Zhongyi Zhang, Jinjin Dai, Yujie Tan, Shasha Wang, Wanjiang Li, Chengxin Niu, Teng Cai, Na Wang, Guangyin Zhen*. Sulfate radicals-based advanced oxidation technology in various environmental remediation: A state-of-the–art review. Chemical Engineering Journal, 402 (2020) 126232.

[74] Yang Yinchuan, Cui He, Zhen Guangyin, Huang Minsheng*, Li Cong. Tubular reactor-enhanced ecological floating bed achieves high nitrogen removal from secondary effluents of wastewater treatment. Environmental Chemistry Letters, DOI: 10.1007/s10311-019-00956-z, APR 2020.

[73] Chengxin Niu, Yang Pan, Xueqin Lu, Shasha Wang, Zhongyi Zhang, Chaoting Zheng, Yujie Tan, Guangyin Zhen*, Youcai Zhao, Yuyou Li. Mesophilic anaerobic digestion of thermally hydrolyzed sludge in anaerobic membrane bioreactor: Long-term performance, microbial community dynamics and membrane fouling mitigation. Journal of Membrane Science, 2020, 612: 118264.

[72] Chengxin Niu, Zhongyi Zhang, Yang Pan, Yujie Tan, Xueqin Lu, Guangyin Zhen*. Does the combined free nitrous acid and electrochemical pretreatment increase methane productivity by provoking sludge solubilization and hydrolysis? Bioresource Technology, 2020, 304: 123006.

[71] Yujie Tan, Chaoting Zheng, Teng Cai, Chengxin Niu, Shasha Wang, Yang Pan, Xueqin Lu, Guangyin Zhen*, Guangren Qian, Youcai Zhao. Anaerobic bioconversion of petrochemical wastewater to biomethane in a semi-continuous bioreactor: Biodegradability, mineralization behaviors and methane productivity. Bioresource Technology, 2020, 304:123005.

[70] Teng Cai, Lijun Meng, Gang Chen, Yu Xi, Nan Jiang, Jialing Song, Shengyang Zheng, Yanbiao Liu, Guangyin Zhen, Manhong Huang*. Application of advanced anodes in microbial fuel cells for power generation: A review. Chemosphere, 2020, 248: 125985.

[69]X Li, Y Zhan, L Su*, Y Chen, M Chen, L Zhang*, G.Y. Z‍hen, Z Han, X Chai. Sequestration of sulphide from biogas by thermal-treated iron nanoparticles synthesized using tea polyphenols. Environmental Technology, 2020, 41(6): 741-750.

[68] R. Yukesh Kannah, S. Kavitha, M. Gunasekaran, Gopalakrishnan Kumar*, J. Rajesh Banua*, Guangyin Zhen. Biohydrogen production from seagrass via novel energetically efficient ozone coupled rotor stator homogenization. International Journal of Hydrogen Energy, 2020,45(10):5881-5889.

[67] Zhang Pengshuai, Liu Changqing*, Zheng Yuyi*, Zhao Youcai, Zhen Guangyin. Statistical key factors optimization of conditions for bio-hydrogen production from sewage sludge and food waste by anaerobic co-digestion. ENERGY & FUELS, 2019,33(11): 11163-11172.

[66]Guangyin Zhen*, Yang Pan, Xueqin Lu, Yu-You Li, Zhongyi Zhang, Chengxin Niu, Gopalakrishnan Kumar, Takuro Kobayashi, Youcai Zhao, Kaiqin Xu (2019). Anaerobic membrane bioreactor towards biowaste biorefinery and chemical energy harvest: Recent progress, membrane fouling and future perspectives. Renewable and Sustainable Energy Reviews, 2019,115:109392.

[65]Jianhui Wang, Yujie Tan, Yang Pan, Guangyin Zhen*, Xueqin Lu*, Yu Song, Youcai Zhao, and Uthira Krishnan Ushani (2019). Altering extracellular biopolymers and water distribution of waste activated sludge by Fe(II)-persulfate oxidation with natural zeolite and polyelectrolyte as skeleton builders for positive feedbacks to dewaterability. ACS Sustainable Chemistry & Engineering, 2019, 7 (19), 16549-16559.

[64] Xuefeng Zhu*, Liang Zhao, Fengying Fu, Zebin Yang, Fan Li, Wenyi Yuan*, Mingyuan Zhou, Wei Fang, Guangyin Zhen, Xueqin Lu, Xuedong Zhang* (2019). Pyrolysis of pre-dried dewatered sewage sludge under different heating rates: Characteristics and kinetics study. Fuel, 255, 115591.

[63]Guangyin Zhen*, Yujie Tan, Taipu Wu, Jianhui Wang, Xueqin Lu**, Youcai Zhao, Xuefeng Zhu, Jing Niu, Jianying Xiong (2019). Strengthened dewaterability of coke-oven plant oily sludge by altering extracellular organics using Fe (II)-activated persulfate oxidation. Science of The Total Environment, 688, 1155-1161.

[62]M Dinesh Kumar, S Kaliappan, S Gopikumar, Guangyin Zhen, J Rajesh Banu*. Synergetic pretreatment of algal biomass through H₂O₂ induced microwave in acidic condition for biohydrogen production. Fuel, 2019, 253, 833-839.

[61] He Cui, Yinchuan Yang, Yu Ding, Dan Li, Guangyin Zhen* (corresponding author), Xueqin Lu, Minsheng Huang*, Xiao Huang. A novel pilot‐scale tubular bioreactor enhanced floating treatment wetland (TB-EFTW) for efficient in‐situ nitrogen removal from urban landscape water: Long term performance and microbial mechanisms. Water Environment research: a Research Publication of the Water Environment Federation, 2019, 91(11):1498-1508.

[60] Xuefeng Zhu, Wenyi Yuan, Maoqian Lang,Guangyin Zhen*(corresponding author), Xuedong Zhu**, Xueqin Lu (2019). Novel methods of sewage sludge utilization for photocatalytic degradation of tetracycline-containing wastewater. Fuel, 252, 148-156.

[59] Yang Pan, Zhongxiang Zhi,Guangyin Zhen*(corresponding author), Xueqin Lu**, Péter Bakonyi, Yu-You Li, Youcai Zhao, J. Rajesh Banu (2019). Synergistic effect and biodegradation kinetics of sewage sludge and food waste mesophilic anaerobic co-digestion and the underlying stimulation mechanisms.Fuel, 253, 40-49,Article accepted for publication 14 Apr 2019.

[58]Zhongyi Zhang, Ying Song, Shaojuan Zheng, Guangyin Zhen*, XueqinLu, Kobayashi Takuro, KaiqinXu, PéterBakonyi, (2019). Electro-conversion of carbon dioxide (CO₂) to low-carbon methane by bioelectromethanogenesis process in microbial electrolysis cells: The current status and future perspective. Bioresource Technology, 279, 339-349..

[57]Zhongxiang Zhi, Yang Pan, Xueqin Lu, Guangyin Zhen*, Youcai Zhao, Xuefeng Zhu, Jianying Xiong, Tianbiao Zhao, (2019). Electrically regulating co-fermentation of sewage sludge and food waste towards promoting biomethane production and mass reduction. Bioresource Technology, 279, 218-227(Cover page).

[56]Guangyin Zhen¹, Jianhui Wang¹, Xueqin Lu *, Lianghu Su, Xuefeng Zhu, Tao Zhou, Youcai Zhao (2019). Effective gel-like floc matrix destruction and water seepage for enhancing waste activated sludge dewaterability under hybrid microwave-initiated Fe(II)-persulfate oxidation process.Chemosphere, 221, 141-153.

[55] V. Godvin Sharmila, M.Gunasekaran, S. Angappanec, Guangyin Zhen, IckTae Yeom, J. Rajesh Banu*, (2019). Evaluation of photocatalytic thin film pretreatment on anaerobic degradability of exopolymer extracted biosolids for biofuel generation. Bioresource Technology, 279, 132-139.

[54] László Koók, Péter Bakonyi, Falk Harnisch, Jörg Kretzschmar, Kyu-Jung Chae, Guangyin Zhen, Gopalakrishnan Kumar*, Tamás Rózsenberszki, Gábor Tóth, Nándor Nemestóthy, Katalin Bélafi-Bakó, (2019). Biofouling of membranes in microbial electrochemical technologies: Causes, characterization methods and mitigation strategies. Bioresource Technology, 279, 327-338.

[53] Gopalakrishnan Kumar*, Dinh Duc Nguyen, Menghour Huy, Periyasamy Sivagurunathan, Péter Bakonyi, Guangyin Zhen, Takuro Kobayashi*, Kai Qin Xu, Nándor Nemestóthy, Soon Woong Chang, (2019).Effects of light intensity on biomass, carbohydrate and fatty acid compositions of three different mixed consortia from natural ecologicalwater bodies. Journal of Environmental Management, 230: 293–300.

[52] Guangyin Zhen, Shaojuan Zheng, Xueqin Lu*, Xuefeng Zhu, Juan Mei, Takuro Kobayashi, Kaiqin Xu, Yu-You Li, Youcai Zhao (2018). A comprehensive comparison of five different carbon-based cathode materials in CO₂ electromethanogenesis: long-term performance, cell-electrode contact behaviors and extracellular electron transfer pathways.Bioresource Technology, 2018, 266:382–388.

[51] Zhen, G.Y.*, Lu, X.Q.*,Lianghu Su; Takuro Kobayashi; Gopalakrishnan Kumar; Tao Zhou; Kaiqin Xu; Yu-You Li; Xuefeng Zhu; Youcai Zhao, (2018). Unraveling the catalyzing behaviors of different iron species (Fe²⁺ vs. Fe⁰) in activating persulfate-based oxidation process with implications to waste activated sludge dewaterability. Water Research,134, 101–114.Pub Date:2018-02-03,DOI 10.1016/j.watres.2018.01.072 (ESI highly cited paper, data from ESI).

[50] Péter Bakonyi, László Koók, Gopalakrishnan Kumar*, Gábor Tóth, Tamás Rózsenberszki, Dinh Duc Nguyen, Soon Woong Chang, Guangyin Zhen, Katalin Bélafi-Bakó, NándorNemestóthy. Architectural engineering of bioelectrochemical systems from the perspective of polymeric membrane separators: A comprehensive update on recent progress and future prospects. Journal of Membrane Science, 2018,564: 508-522.

[49] Yong Hu, Takuro Kobayashi*, Guangyin Zhen, Chen Shi, Kai-Qin Xu*, (2018). Effects of Lipid concentration on thermophilic anaerobic co-digestion of food waste and grease waste in a siphon-driven self-agitated anaerobic reactor. Biotechnology Reports, BTRE_e00269, Article accepted for publication, 19 Jun 2018.

[48] Periyasamy Sivagurunathan, Chandrasekhar Kuppam, Ackmez Mudhoo, Ganesh D. Saratale, Abudukeremu Kadier, Guangyin Zhen, Lucile Chatellard, Eric Trably & Gopalakrishnan Kumar. A comprehensive review on two-stage integrative schemes for the valorization of dark fermentative effluents. Critical Reviews in Biotechnology, 2018, 38(6):868-882, Published online: ‍‍21 Dec 2017.

[47]Lu, X.Q., Ni, J.L.,Zhen, G.Y., Kubota, K., Li Y.Y.* (2018). Responses of morphology and microbial community of granules to influent COD/SO₄^2– ratios in an upflow anaerobic sludge blanket (UASB) reactor treating starch wastewater. Bioresource Technology, 256,456–465.

[46] Tao Zhou, Sheng Huang, Dongjie Niu, Lianghu Su, Guangyin Zhen, Youcai Zhao* (2018).Efficient Separation of Water-Soluble Humic Acid Using (3-Aminopropyl)triethoxysilane (APTES) for Carbon Resource Recovery from Wastewater. ACS Sustainable Chem. Eng., 6 (5), 5981-5989, DOI: 10.1021/acssuschemeng.7b04507.

[45] Lianghu Su, Chenwei Liu, Kangkang Liang, Yudong Chen, Longjiang Zhang, Xiaolin Li, Zhihua Han, Guangyin Zhen, Xiaoli Chai, Xu Sun. Performance evaluation of zero-valent iron nanoparticles (NZVI) for high-concentration H2S removal from biogas at different temperatures. RSC Advances, 2018, 8(25), 13798-13805.

[44]Zhen, G.Y.*, Lu, X.Q.*, Kumar, G., Bakonyi, P., Xu, K.Q.*, Zhao, Y.C. (2017). Microbial electrolysis cell platform for simultaneous waste biorefinery and clean electrofuels generation: Current situation,challenges and future perspectives. Progress in Energy and Combustion Science, 63, 119-145 (SCI-IF 25.242).

[43] G Kumar, P Sivagurunathan, GY Zhen, T Kobayashi, SH Kim, K Xu (2017). Combined pretreatment of electrolysis and ultra-sonication towards enhancing solubilization and methane production from mixed microalgae biomass. Bioresource Technology, 245, 196-200.

[42]G Kumar, P Sivagurunathan, GY Zhen, T Kobayashi, KQ Xu (2017). Harnessing of bioenergy from different mixed microalgae consortia obtained from natural ecological niches. Renewable Energy Focus 21, 11-15.

[41] Zhen, G.Y, Lu, X.Q., Kobayashi, T., Su, L.,Kumar, G., Bakonyi, P., He, Y., Sivagurunathan, P., Nemestóthy, N., Xu, K.Q.*, (2017). Continuous micro-current stimulation to upgrade methanolic wastewater biodegradation and biomethane recovery in an upflow anaerobic sludge blanket (UASB) reactor. Chemosphere, 180, 229–238.

[40]Saratale, GD; Saratale, RG; Shahid, MK; Zhen, GY; Kumar, G; Shin, HS; Choi, YG; Kim, SH. (2017). A comprehensive overview on electro-active biofilms, role of exo-electrogens and their microbial niches in microbial fuel cells (MFCs). CHEMOSPHERE, Volume: 178 Pages: 534-547.

[39]Rijuta Ganesh Saratale, Ganesh Dattatraya Saratale, Arivalagan Pugazhendhi, Guangyin Zhen, Gopalakrishnan Kumar, Abudukeremu Kadier, Periyasamy Sivagurunathan, (2017). Microbiome involved in microbial electrochemical systems (MESs): A review. Chemosphere, 177, 176-188

[38]Gopalakrishnan Kumar, Rijuta Ganesh Saratale, Abudukeremu Kadier, Periyasamy Sivagurunathan, Guangyin Zhen, Sang-Hyoun Kim, Ganesh Dattatraya Saratale, (2017). A review on bio-electrochemical systems (BESs) for the syngas and value added biochemicals production. Chemosphere, 177, 84-92.

[37] Rijuta Ganesh Saratale, Chandrasekar Kuppam, Ackmez Mudhoo, Ganesh Dattatraya Saratale, Sivagurunathan Periyasamy, Guangyin Zhen, László Koók, Péter Bakonyi, Nándor Nemestóthy, (2017). Bioelectrochemical systems using microalgae – A concise research update. Chemosphere, 177, 35–43.

[36] Koók, L., Nemestóthy, N., Bakonyi, P., Zhen, G.Y, Kumar, G., Lu, X.Q., et al. (2017). Performance evaluation of microbial electrochemical systems operated with nafion and supported ionic liquid membranes. Chemosphere, 175, 350-355.

[35] Zhen, G.Y, Lu, X.Q., Kato, H., Zhao, Y.C., Li, Y.Y., (2017). Overview of pretreatment strategies for enhancing sewage sludge disintegration and subsequent anaerobic digestion: current advances, full-scale application and future perspectives. Renewable & Sustainable Energy Reviews, 69, 559-577 （被IWA国际水协会专题报道--预处理 |提高污泥降解和强化厌氧消化的策略，原创2017-10-13IWA国际水协会，http://mp.weixin.qq.com/s/11AcszAlRZ948EDO92KVhg；(ESI highly cited paper, data from ESI，热点论文; The most cited articles published in Renewable & Sustainable Energy Reviews Articles since 2017, extracted from homepage of the Journal)）.

[34] Lu, X.Q., Zhen, G.Y.^* (corresponding author), Ni, J., Kubota, K., Li, Y.Y.^** (2017). Sulfidogenesis process to strengthen re-granulation for biodegradation of methanolic wastewater and microorganisms evolution in an UASB reactor. Water Research, 108, 137–150.

[33] Bakonyi, P., Kumar, G., Zhen, G.Y., Sivagurunathan, P., Koók, L., Kim, S.H, Toth, G., Nemestóthy, N.,Bélafi-Bakó, K., (2017). Microbial electrochemical systems for sustainable biohydrogen production: Surveying the experiences from a start-up viewpoint. Renewable & Sustainable Energy Reviews, 70, 589–597 (ESI highly cited paper, data from ESI).

[32]Zhen, G.Y., Lu, X.Q., Kobayashi, T., Kumar, G., Xu, K.Q.*, (2016). Promoted electromethanosynthesis in a two-chamber microbial electrolysis cells (MECs) containing a hybrid biocathode covered with graphite felt (GF). Chemical Engineering Journal, 284: 1146-1155. http://dx.doi.org/10.1016/j.cej.2015.09.071. (ESI highly cited paper, data from ESI).

[31]Zhen, G.Y., Kobayashi, T., Lu, X.Q., Kumar, G., Xu, K.Q*. (2016). Biomethane recovery from Egeria densa in a microbial electrolysis cells (MEC)-assisted anaerobic system: performance and stability assessment. Chemosphere, 149: 121-129. 10.1016/j.chemosphere.2016.01.101. (ESI highly cited paper, data from ESI).

[30] Zhen, G.Y., Lu, X.Q., Kobayashi, T., Kumar, G., Xu, K.Q.* (2016). Anaerobic co-digestion on improving methane production from mixed microalgae (Scenedesmus sp., Chlorella sp.) and food waste: kinetic modelling and synergistic impact evaluation. Chemical Engineering Journal, 299: 332-341 (ESI highly cited paper, data from ESI; Cover Page of the Volume 299).

[29]Zhen, G.Y., Kobayashi, T., Lu, X.Q., Kumar, G., Hu, Y., Bakonyi, P., Rózsenberszki, T., Koók, L., Nemestóthy, N., Bélafi-Bakó, K., Xu, K.Q.*, (2016). Recovery of biohydrogen in a single-chamber microbial electrohydrogenesis cell using liquid fraction of pressed municipal solid waste (LPW) as substrate. International Journal of Hydrogen Energy, 41(40): 17896-17906.

[28] Lu, X.Q., Zhen, G.Y., Ni, J.L., Hojoa, T., Kubota, K., Li, Y.Y. (2016). Effect of influent COD/SO₄^2- ratios on biodegradation behaviors of starch wastewater in an upflow anaerobic sludge blanket (UASB) reactor. Bioresource Technology, 214: 175-183.

[27] Kumar, G., Zhen, G.Y., Kobayashi, T., Sivagurunathan, P., Kim, S.H, Xu, K.Q. (2016). Impact of pH control and heat pre-treatment of seed inoculum in dark H₂ fermentation: a feasibility report using mixed microalgae biomass as feedstock. International Journal of Hydrogen Energy, 41(7): 4382–4392.

[26] Kumar, G., Zhen, G.Y., Sivagurunathan, P., Bakonyi, P., Nemestóthy, N., Bélafi-Bakó, K., Kobayashi, T., Xu, K.Q. (2016). Biogenic H₂ production from mixed microalgae biomass: impact of pH control and methanogenic inhibitor (BESA) addition. Biofuel Research Journal, 3(3): 470-474.

[25] Lu, X.Q., Chen, S.P, Luo, J.H., Qian, G.R., Liu, J.Y., Zhen, G.Y, Li Y.Y., (2016). Application of a CO2-stripping system for calcium removal to upgrade organic matter removal and sludge granulation in a leachate-fed EGSB bioreactor. RSC Advances, 6(11): 9286-9296.

[24] Bednára, A., Nemestóthy, N., Bakonyi, P., Fülöp, L., Zhen, G.Y, Lu, X.Q., Kobayashi, T., Kumar, G., Xu, K.Q., Bélafi-Bakó K. (2016). Enzymatically-boosted ionic liquid gas separation membranes using carbonic anhydrase of biomass origin. Chemical Engineering Journal, 303: 621-626.

[23] Kumar, G., Sivagurunathan, P., Thi, N.B.D., Zhen, G.Y., Kobayashi, T., Kim, S.H., Xu, K.Q., (2016). Evaluation of different pretreatments on organic matter solubilization and hydrogen fermentation of mixed microalgae consortia. International Journal of Hydrogen Energy, 41(46): 21628–21640.

[22] Kumar, G., Sivagurunathan, P., Pugazhendhi, A., Thi, N.B.D., Zhen, G.Y., Kuppam, C., Kadier, K., (2017). A comprehensive overview on light independent fermentative hydrogen production from wastewater feedstock and possible integrative options. Energy Conversion and Management, 2017, 141: 390-402 (ESI highly cited paper, data from ESI).

[21] Zhen, G.Y, Lu, X.Q., Kobayashi, T., Li Y.Y., Xu, K.Q., Zhao, Y.C. (2015). Mesophilic anaerobic co-digestion of waste activated sludge and Egeria densa: Performance assessment and kinetic analysis. Applied Energy, 148: 78-86.

[20]Zhen, G.Y, Kobayashi, T., Lu, X.Q., Xu, K.Q.*, (2015). Understanding methane bioelectrosynthesis from carbon dioxide in a two-chamber microbial electrolysis cells (MECs) containing a carbon biocathode. Bioresource Technology, 186: 141-148.

[19] Zhen, G.Y., Lu, X.Q., Li Y.Y., Liu Y., Zhao, Y.C. (2015). Influence of zero valent scrap iron (ZVSI) supply on methane production from waste activated sludge. Chemical Engineering Journal, 263: 461–470.

[18] Mei, J., Zhen, G.Y., (Co-first author) Zhao, Y.C. (2015) Bio-oxidation of escape methane from landfill using leachate-modified aged refuse. The Arabian Journal for Science and Engineering, 41(7): 2493–2500.

[17] Lu, X.Q., Zhen, G.Y., Adriana L.E., Chen, M., Ni, J.L., Hojoa, T., Kubota, K., Li, Y.Y. (2015). Operation performance and granule characterization of upflow anaerobic sludge blanket (UASB) reactor treating wastewater with starch as the sole carbon source. Bioresource Technology, 180: 264–273.

[16] Lu, X.Q., Zhen, G.Y., Chen, M., Kubota, K., Li, Y.Y. (2015). Biocatalysis conversion of methanol to methane in an upflow anaerobic sludge blanket (UASB) reactor: long-term performance and inherent deficiencies. Bioresource Technology, 198: 691–700.

[15] Su, L., Zhen, G.Y., Zhang, L., Zhao, Y.C., Niu, D., Chai, X. (2015). The use of the core–shell structure of zero-valent iron nanoparticles (NZVI) for long-term removal of sulphide in sludge during anaerobic digestion. Environmental Science: Processes & Impacts, 17(12): 2013-2021.

[14] Gao, X., Gu, Y., Xie, T., Zhen, G.Y., Huang, S., Zhao, Y.C. (2015). Characterization and environmental risk assessment of heavy metals in construction and demolition wastes from five sources (chemical, metallurgical and light industries, and residential and recycled aggregates). Environmental Science and Pollution Research, 22(12): 9332-9344.

[13] Gao, X., Gu, Y., Huang, S., Zhen, G.Y., Deng, G., Xie, T., Zhao, Y.C. (2015). Comparison of alternative remediation technologies for recycled gravel contaminated with heavy metals. Waste Management & Research, DOI: 10.1177/0734242X15602963.

[12] Lu, X.Q.,Zhen, G.Y.^*,Liu Y., Hojo, T., Adriana L.E., Li, Y.Y. (2014). Long-term effect of the antibiotic cefalexin on methane production during waste activated sludge anaerobic digestion. Bioresource Technology,169: 644–651 (Corresponding author).

[11]Guangyin Zhen^*, Xueqin Lu, Yu-You Li^*, Youcai Zhao (2014). Combined electrical-alkali pretreatment to increase the anaerobic hydrolysis rate of waste activated sludge during anaerobic digestion. Applied energy, 128: 93–102 (SCI-IF=5.613, ESI highly cited paper, data from ESI).

[10] Zhen, G.Y., Lu, X.Q., Wang, B.Y., Zhao, Y.C., Chai, X.L., Niu, D.J., Zhao, T.T. (2014). Enhanced dewatering characteristics of waste activated sludge with Fenton pretreatment: Effectiveness and statistical optimization. Frontiers of Environmental Science and Engineering, 8(2): 267–276.

[9] Zhen, G.Y., Lu, X.Q., Li, Y.Y., Zhao, Y.C. (2013). Innovative combination of electrolysis and Fe(II)-activated persulfate oxidation for improving the dewaterability of waste activated sludge. Bioresource Technology, 136: 664–663.

[8] Zhen, G.Y., Lu, X.Q., Zhao, Y.C., Niu, J., Chai, X.L., Su, L.H., Li, Y.Y., Liu, Y., Du, J.R., Hojo, T., Hu, Y. (2013). Characterization of controlled low-strength material (CLSM) obtained from dewatered sludge and MSWI bottom ash: Mechanical and microstructural perspectives. Journal of Environmental Management, 129: 183–189.

[7] Zhen, G.Y., Lu, X.Q., Niu J., Su, L. H., Chai, X.L., Zhao, Y.C., Li Y. Y., Song Y., Niu, D.J. (2013). Inhibitory effects of a shock load of Fe(II)-mediated persulfate oxidation on waste activated sludge anaerobic digestion. Chemical Engineering Journal, 233: 274–281.

[6] Zhen, G.Y., Lu, X.Q., Zhao, Y.C., Chai, X.L., Niu, D.J. (2012). Enhanced dewaterability of sewage sludge in the presence of Fe(II)-activated persulfate oxidation. Biorecourse Technology, 116: 259–265.

[5] Zhen, G.Y., Lu, X.Q., Li, Y.Y., Zhao, Y.C., Wang, B.Y., Song, Y., Chai, X.L., Niu, D.J., Cao, X.Y., (2012). Novel insights into enhanced dewaterability of waste activated sludge by Fe(II)-activated persulfate oxidation. Bioresource Technology, 119: 7–14.

[4] Zhen, G.Y., Lu, X.Q., Wang, B.Y, Zhao, Y.C., Chai, X.L., Niu, D.J., Li, Y.Y., Song, Y., Cao, X.Y. (2012). Synergetic pretreatment of waste activated sludge by Fe(II)-activated persulfate oxidation under mild temperature for enhanced dewaterability. Bioresource Technology,124: 29–36.

[3] Zhen, G.Y., Lu, X.Q., Cheng, X.B., Chen, H., Yan, X.F., Zhao, Y.C. (2012). Hydration process of the aluminate 12CaO·7Al₂O₃-assisted Portland cement-based solidification/ stabilization of sewage sludge. Construction and Building Materials, 5(30): 675–681.

[2] Zhen, G.Y., Zhou, H.Y., Zhao T.T., Zhao Y.C. (2012). Performance appraisal of controlled low-strength material (CLSM) using sewage sludge and refuse incineration bottom ash. Chinese Journal of Chemical Engineering, 20(1): 80–88.

[1] Zhen, G.Y., Yan, X.F., Zhou, H.Y., Chen, H., Zhao, T.T., Zhao, Y.C. (2011). Effects of calcined aluminum salts on the advanced dewatering and solidification/stabilization of sewage sludge. Journal of Environmental Science, 23 (7): 1225–1232.

-中（日）文学术论文：

[32] 李钰辉，卓桂华，沈凯茜，李海霞，景乐，陈琬，甄广印，郑育毅*. 磁改性污泥基生物炭对猪粪堆肥及土霉素降解的影响，环境科学学报，DOI：10.13671/j.hjkxxb.2023.0379。

[31]鄢胜韩，黄恒旭，卓桂华，曾艺芳，江娟，刘常青，甄广印，郑育毅*. 不同比例葡萄糖和蛋白质对微生物电解池产氢影响，中国给水排水，2023，39(13)，95-102.

[30]支忠祥，韩宇乐，陆雪琴，孙雨薇，甄广印*. 间歇通电和电极反转对MEC-CSTR反应器污泥餐厨垃圾协同厌氧消化的影响，能源环境保护，2023，37(05)，121-128.

[29]王佳懿, 陆雪琴, 甄广印*. 微生物电解池催化CO₂电转化为甲烷：影响因素、电子传递和展望. 环境化学，2024，43(2): 1-12

[28]甄广印*，王娜，王佳懿，陆雪琴，邱博然. 微生物电解池CO₂电甲烷化的影响因素及电子中介体角色探究.能源环境保护，2023（网络首发：2023-01-09）.

[27]戴启才，张瑞良，殷健，秦曦，刘兆斌，甄广印*，陆雪琴. 碱联合微波预处理污泥及交联聚合回收上清液中有机质和氮磷.环境化学，2023（网络首发：2022-10-27）.

[26]江丽华，卓桂华，陈细妹，林鸿，刘常青*，甄广印，郑育毅. 药剂联合高温对低有机质污泥水解促进研究. 中国给水排水，2022，38(19)：86-92.

[25] 王永萍，方皓珏，华若婷，何雨恒，张燕琼，郑育毅，刘常青*，甄广印. 多因素共同作用对中温条件下污泥与餐厨垃圾联合厌氧发酵产H₂的影响. 环境工程，2023（网络首发：2022-09-22）.

[24] 曹麒，鄢胜韩，庄廷烽，郑思颖，刘常青*，曾艺芳，郑育毅，甄广印. 预处理污泥发酵液直接用于微生物电解池产氢研究. 环境科学学报，2023，43(03)：234-243.

[23] 邹亚娜，臧越，王恺元，秦曦，甄广印*，陆雪琴. 生物电催化调控污泥-餐厨垃圾协同厌氧产酸研究. 环境化学，2023，42(01)：298-309.

[22] 沙小涵, 任璇, 牛承鑫, 陆雪琴, 甄广印*. 微波-Fe(II)/S2O82-耦合强化污泥溶胞与定向甲烷转化研究. 环境化学, 2021，40（9）：1-12..

[21]潘阳,牛承鑫,支忠祥,王建辉,陆雪琴,戴金金,甄广印*,孙彤彤,康娜英, 纳米零价铁强化微生物电催化-厌氧膜生物组合反应器抗膜污染能力及其调控机制. 环境科学, 2020, 41（11）：5073-5081. DOI：10.13227/j.hjkx.202003164

[20]胡维杰, 赵由才, 甄广印, 德国污水污泥处理处置政策及磷回收技术解析与启示. 给水排水. 2020,6:15-20.

[19]潘阳，支忠祥，牛承鑫，陆雪琴，甄广印*. 厌氧膜生物反应器的现状、挑战和前景. 环境污染与防治，2020，４２(１):101-106.

[18] 周昱晗，潘阳，张瑞良，郑朝婷，支忠祥，甄广印*. 酸碱-微波耦合预处理对污泥胞外聚合物溶裂与产甲烷行为的影响研究. 环境工程，2020，38（12）：54-61.

[17] 戴金金，牛承鑫，潘阳，陆雪琴，甄广印*，郑朝婷，张瑞良，何欣昱. 基于厌氧膜生物反应器的剩余污泥-餐厨垃圾厌氧共消化性能. 环境科学，2020，41（8）：3740-3747.

[16] 戴金金，牛承鑫，潘阳，陆雪琴，甄广印*. 厌氧膜生物反应器污泥处理与膜污染控制研究进展. 环境化学，2020（已录用）.

[15] 郑朝婷，潘阳，陆雪琴*，甄广印，宋玉，赵由才. 甲醇废水厌氧生物处理的研究进展. 水处理技术，2020（已录用）.

[14] 王沙沙，潘阳，谭宇杰，甄广印*，陆雪琴. 厌氧氨氧化：技术现状、研究进展及主要影响因素. 环境卫生工程，2020，2020,1:64-69+73.

[13]牛承鑫，潘阳，陆雪琴，甄广印*，张衷译，宋玉，赵由才. 厌氧膜生物反应器(AnMBR)膜污染过程及控制方法研究进展. 环境化学, 2019,38(12):2851-2859.

[12] 甄广印，吴太朴，陆雪琴，王建辉，赵由才，黄民生，何岩，梁松波，宋玉，刘德滨，孟龙.高级氧化污泥深度脱水技术研究进展. 环境污染与防治, 2019,41(98):1108-1113,1119.

[11] 郑韶娟，陆雪琴，张衷译，甄广印*，赵由才(2019). 微生物电解池：生物电催化辅助CO₂甲烷化技术. 环境化学，38(7): 1666-1674.

[10] 苏良湖, 张明珠, 张龙江, 甄广印, 柴晓利, 赵由才* (2017). 水合氧化铁对污泥厌氧消化过程的硫化氢控制. 中国环境科学, 37(4) :1349-1357.

[9] 甄広印，胡勇，小林拓朗，徐開钦 (2016). 微生物電気分解を用いたエネルギー回収型排水処理技術の進展.『用水と廃水』，58(10): p. 759-767.

[8] 罗安然, 甄广印, 龙吉生, 白力, 周家珍, 劳云枫, 赵由才 (2016). Fenton预处理强化污泥脱水: 胞外聚合物和黏度的特性研究. 环境工程, 34(2): 127-132.

[7]甄广印, 龙吉生, 白力, 赵由才. 污泥脱水性能的影响因素解析[J]. 有色冶金设计与研究，2015, 36(4): 56-61.

[6] 劉媛，北條俊昌，何士龍，甄広印，李玉友.　酸素制御による部分的亜硝酸化の実現と維持. 土木学会論文集Ｇ（環境），2014,70（7）：Ⅲ_233–Ⅲ_241.

[5] 甄广印，陆雪琴，汪宝英，宋玉，柴晓利，牛冬杰，赵由才. 碱性添加剂对污泥厌氧发酵产甲烷的影响.环境卫生工程，2012，20 (4): 1–4.

[4] 甄广印，周海燕，赵由才. 城市污水厂污泥铝基凝胶固化剂固化／稳定化研究，2011年中国城镇污泥处理处置技术与应用高级研讨会论文集，中国青岛，2011年5月，pp. 79–86.

2010:

[3] 甄广印，刘大江，赵由才.城市污泥填埋气集气井收集系统的优化研究. 环境污染与防治，2010，32 (2): 33–36.

[2] 甄广印，赵由才，宋玉，曹先艳.城市污泥处理处置技术研究.有色冶金设计与研究，2010，31 (5): 41–45.

[1] 甄广印，周海燕，宋玉，苏冬云，柴晓利，牛冬杰，赵由才. 十二烷基苯磺酸钠(SDBS)-氢氧化钠耦合污泥脱水技术研究.环境化学，2010，29 (6): 1106–1110.

PATENTS（国家发明专利）:

[20] 甄广印，陆雪琴，刘新宇，张衷译，蔡腾，一种基于生物电化学的脱氮除硫反应装置，中国发明专利，专利号：ZL 2021 1 1042402.4, 授权公告日：2023年06月09日；授权公告号：CN 113800620 B。

[19] 邱博然，王恺元，衡世亮，甄广印，一种碳点联合电膜强化污泥甲烷转化和抗膜污染的方法，中国发明专利，专利号：ZL 202211284759.8，申请日：20221020.授权公告日：2023年09月29日授权公告号：CN 115448559 B。

[18]陆雪琴，郑朝婷，甄广印，王越，谭宇杰，李万江，周昱晗，一种中空纤维膜反应器处理石化废水的方法，实用新型专利，申请中。

[17] 陆雪琴，郑朝婷，甄广印，王越，谭宇杰，李万江，周昱晗，一种中空纤维膜反应器处理石化废水的方法，中国发明专利，申请号：202010017651.7，申请日2020-01-08。

[16]甄广印，谭宇杰，牛承鑫，王沙沙，郑朝婷，一种污泥驱水调理剂的制备方法及其应用，中国发明专利，申请号：202010047231.3，申请日2020-01-16。

[15]甄广印，王建辉，陆雪琴，潘阳，支忠祥，郑韶娟，张衷译，一种复合型污泥破解驱水调理剂及其应用，中国发明专利，申请号：201810905934.8（实质审查）.

[14] 甄广印，潘阳，陆雪琴，王建辉，支忠祥，郑韶娟，张衷译，一种电极耦合平板膜的厌氧电化学污泥处理装置，中国发明专利，申请号：201910405884.1，申请日：20190808；

[13] 甄广印，潘阳，陆雪琴，王建辉，支忠祥，郑韶娟，张衷译，一种电极耦合平板膜的厌氧电化学污泥处理装置，中国实用新型专利，专利号：201920698378.1，申请日：20190516；授权公告日：2020-04-10.

[12] 甄广印，郑韶娟，陆雪琴，张衷译，王建辉，潘阳，一种微生物电解池及有机氧化物降解同步CO₂甲烷化方法，中国发明专利，申请号：201910413809.X（实质审查），申请日：20190808.

[11] 甄广印，郑韶娟，陆雪琴，张衷译，王建辉，潘阳，一种有机氧化物降解同步CO₂甲烷化的微生物电解池，中国实用新型专利，专利号：201920711402.0，申请日：20190517；授权公告日：2020-04-10.

[10] 甄广印，王建辉，陆雪琴，潘阳，谭宇杰，一种生物膜反应器同步污泥处理系统及其污泥处理方法，中国发明专利，申请号：201910383701.0（实质审查），申请日：20190808.

[9] 甄广印，王建辉，陆雪琴，潘阳，谭宇杰，一种生物膜反应器的膜污染防控同步污泥处理装置，中国实用新型专利，申请号：201920647545.X；申请日：20190508；授权公告日：2020-04-10.

[8]陈宏, 王泓, 韦燕霄, 杜春艳, 刘兵, 田红, 周璐, 甄广印, 郭延, 胡颖冰. 一种生物膜强化脱氮处理工艺: 中国发明专利. 申请号: 2017114293088. 申请日: 2017-12-26.

[7]赵由才；甄广印；程晓波；陈华；周海燕；黄仁华.一种城市污水厂脱水污泥铝基胶凝固化剂及其应用.中国发明专利，专利号：ZL 201110079824.9，申请日：20110330；授权公告日：2012-11-07（证书号：第1072664号）（~2016-05-18）.

[6]黄仁华；甄广印；周海燕；徐勤；邵正浩；张美兰；赵由才；苏冬云.一种无机复合污泥脱水调理剂及其应用. 中国发明专利，专利号：ZL 201010198649.0，申请日：20100611；授权公告日：2012-05-23（证书号：第950027号）.

[5]赵由才；宋玉；汪宝英；万琦；甄广印；曹先艳.一种生活垃圾污水处理厂脱水污泥的处理方法.中国发明专利，专利号：ZL 201110133374.7，申请日：20110523；授权公告日：2012-10-03（证书号：第105612号）（2014-08-20专利权转移）.

[4]周海燕；甄广印；徐勤；宋玉；黄仁华；赵由才；张美兰.一种用于处理城市污水处理厂污泥的污泥固化剂及其污泥处理方法.中国发明专利，专利号：ZL 201110191790.2，申请日：20110708；授权公告日：2013-06-26（证书号：第1224535号）.

[3]赵由才；汪宝英；左敏瑜；宋玉；甄广印.一种处理飞灰中二噁英的萃取剂及其萃取二噁英的方法. 中国发明专利，专利号：ZL 201110241836.7，申请日：20110822；授权公告日：2013年10月30日（证书号：第1293699号）（~2017-10-17）.

[2]赵由才；宋玉；汪宝英；甄广印.一种污泥调理剂及使用污泥调理剂的深度脱水方法. 中国发明专利，专利号:ZL 201110279623.3, 申请日20110920；授权公告日：2014年05月21日（证书号：第1406399号）（2017-11-03）.

[1]赵由才；米琼；柴晓利；牛冬杰；甄广印.一种脱水污泥除臭改性及资源化的方法.中国发明专利，专利号：ZL 201310057927. 4，申请日：20130225；授权公告日：2014年08月13日（证书号：第1462221号）.

BOOKS（专著）：

[10]甄广印，陆雪琴，胡维杰，宋玉，赵由才，编著.《易腐有机固废处理与资源化》，北京：冶金工业出版社，2023.9，ISBN 978-7-5024-9515-2.

[9]甄广印，陆雪琴，苏良湖，魏俊，赵由才，编著。《农村生物质综合处理与资源化利用技术》，2019.1，北京-冶金工业出版社，ISBN 978-7-5024-7948-0。

[8] Zhen Guangyin and Zhao Youcai.《Pollution Control and Resource Recovery: Sewage Sludge》. Elsevier Inc., 2016-10-26, ISBN: 978-0-12-811639-5, http://dx.doi.org/10.1016/B978-0-12-811639-5.00001-2.

[7]甄广印，赵由才. 《城市污泥强化深度脱水资源化利用及卫生填埋末端处置关键技术研究》，同济大学出版社，2017年6月第一版、第一次印刷，ISBN 978-7-5608-6975-9.

[6] Periyasamy Sivagurunathan, Gopalakrishnan Kumar, Arivalagan Pugazhendhi, Guangyin Zhen, Takuro Kobayashi and Kaiqin Xu. Chapter 11 Biohydrogen Production from Wastewaters (pp. 197-210), 《Biological Wastewater Treatment and Resource Recovery》edited by Robina Farooq and Zaki Ahmad, ISBN 978-953-51-3046-8, Print ISBN 978-953-51-3045-1, Published: March 29, 2017 under CC BY 3.0 license.

[5]Guangyin Zhen, Xueqin Lu, Xiaohui Wang, Shaojuan Zheng, Jianhui Wang, Zhongxiang Zhi, Lianghu Su, Kaiqin Xu, Takuro Kobayashi, Gopalakrishnan Kumar, Youcai Zhao: Deployment of biogas production technologies in emerging countries (Chapter 20), in book: Green Energy to Sustainability, edited by Alain Vertes, Nasib Qureshi,Hans P. Blaschek and Hideaki Yukawa, John Wiley & Sons, April 2020, DOI: 10.1002/9781119152057.ch16.ISBN: 9781119152026; Publication date: 8^th April 2020; Price: $125 USD/£97.50; https://www.wiley.com/en-gb/Green+Energy+to+Sustainability%3A+Strategies+for+Global+Industries-p-9781119152026.

[4]朱英，张华，赵由才. 《污泥处理与资源化丛书—污泥循环卫生填埋技术》. 冶金工业出版社，2010年05月. 甄广印参编第三、第六章. ISBN：5024-5246-9.

[3]李兵，张承龙，赵由才. 《污泥处理与资源化丛书—污泥表征与预处理技术》. 冶金工业出版社，2010年08月. 甄广印参编第七章. ISBN：978-7-5024-5303-9.

[2]赵由才，甄广印，韩丹，实现生活垃圾最大限度的资源利用，pp 46-49。见寿子琪主编、施强华、马兴发、郁增荣副主编，《科学家带你游世博》，上海科学技术出版社，上海，2010年7月. ISBN：978-7-5478-4/N4.

[1]赵由才. 《固体废物处理与资源化技术》.同济大学出版社，2015年10月. 甄广印参编第七章. ISBN 978-7-5608-6005-3.

软件著作:

邱博然，胡鸣原，甄广印，《生活垃圾分类的碳排放及减碳潜力模型核算系统V1.0》，中国软件著作权，证书号：软著登字第10740622号，申请日：20221221.

ENTERPRISE STANDARD（参编标准）:

[1]黄仁华，周海燕，张美兰，朱集峰，朱利忠，王为民，顾连官，赵由才，甄广印，李强，余召辉. 上海环境实业有限公司企业标准—生活垃圾散装运输作业指导书, Q/HJSY TG3102.16—2015.

[1] 黄仁华，周海燕，张美兰，朱集峰，王为民，朱利忠，顾连官，赵由才，甄广印，李强，余召辉. 企业标准-生活垃圾散装运输作业指导书, Q/LG TG304.1, 发布/实施日期2015-01-01/2015-02-01.

[2]黄仁华，周海燕，张美兰，朱集峰，王为民，朱利忠，顾连官，赵由才，甄广印，李强，余召辉. 企业标准-生活垃圾散装运输作业指导书, Q/LG TG304.2,发布/实施日期2015-01-01/2015-02-01.

[3] 黄仁华，周海燕，张美兰，张军，董辉，唐文荣、唐佶、刘国平、甄广印，李强，余召辉, 企业标准-生活垃圾、污泥卫生填埋作业标准第4部分质量控制与评价改进标准, Q/LG TG311.2, 发布/实施日期2015-01-01/2015-02-01.

ORAL PRESENTATION（国际、国内会议）:

[33] 甄广印（受邀），污泥厌氧消化与生物气衍生CO₂捕获与提质技术研究，首届环境工程学科固废论坛”学术交流研讨会，国家自然科学基金委员会资助、同济大学主办，2023 年 2 月 17-19 日，上海。

[32]甄广印（受邀），污水污泥厌氧甲烷转化与 CO2捕获同步高值品利用研究，第四届西北水环境青年学者论坛（NWEY2022），分论坛十三：废水厌氧处理与资源化，长安大学，2022年 8 月 20-22 日.

[31]甄广印（受邀），有机固废厌氧甲烷转化与 CO₂同步高值品转化研究，第四届中国化学快报青年环境化学家论坛暨2021年中国化学快报环境化学方向青年编委会年会，2021年11月26日-28日，中国哈尔滨，《中国化学快报》编委会。

[30]甄广印（召集人/分会场主持人），污泥厌氧甲烷转化与生物气同步提质，第六届上海生态环保青年科学家高峰论坛，2021年04月23日-24日，中国上海，华东师范大学；

[29] 甄广印，污泥厌氧甲烷转化与生物气提纯，2021年全国有机固废处理与资源化利用高峰论坛，2025-5-15~16，四川成都，中国环境科学学会等（分论坛召集人/主持人）

[28]甄广印，污泥-餐厨垃圾耦合厌氧消化及协同强化机制，2020年全国有机固废处理与资源化利用高峰论坛，2020-11-10~12，湖南长沙，中国环境科学学会等。

[27] 甄广印（受邀），基于微生物电催化诱导CO2燃料化技术研究，生物材料前沿论坛-Living, Dynamic and Soft Matter & Devices，上海科技大学物质学院，2019-11-06.

[26] 甄广印（受邀），污泥调理溶裂预处理与厌氧甲烷转化技术研究，“一带一路”（西安）水处理高峰论坛暨分论坛，西安建筑科技大学，陕西西安开元名都大酒店，2019年12月16日-17日。

[23] 甄广印（受邀报告），污泥调理脱水与厌氧甲烷转化，2019年上海市“资源循环与可持续发展”研究生学术论坛，上海第二工业大学，2019年9月20日。

[22] U. USHANI, Guangyin Zhen(受邀). Enhancement Of Anaerobic Biodegradability Of Municipal Waste Activated Sludge By Immobilized Biological Disintegration, “一带一路”绿色矿业与可持续发展论-Belt and Road Forum on Green Mining for Sustainable Development. 2019 年 5 月 29-31 日，中国地质大学，中国·徐州 May 29 –31,2019 Xuzhou, China.

[21]甄广印（口头报告），污泥调理溶裂驱水与厌氧能源转化关键技术，2019年全国有机固废处理与资源化利用研讨会，安徽合肥（天鹅湖大酒店），中国环境科学学会-同济大学主办，2019.5.9-10.

[20] Xue-Qin Lu (ECNU) (Oral Presentation), Chenglei Xie (Tohoku Univ.), Guangyin Zhen (ECNU), Yu-You Li (Tohoku Univ.). Development and Spatial Microstructure Variation of Membrane Foulants in a Hollow Fiber Anaerobic Membrane Bioreactor for Milk Waste and Sewage Sludge Co-treatment. The 53rd Annual Conference of Japan Society on Water Environment (Lecture No.: 1-I-11-3”) ，pp.76, 2019.3.7~9, University of Yamanashi, Kofu City, Japan (JSWE-IDEA Water Environment International Exchange Award).

[19] Guangyin Zhen*(Oral Presentation), Shaojuan Zheng (ECNU), Xue-Qin Lu (ECNU), Takuro Kobayashi, Kaiqin Xu, Yong HU (NIES).Simultaneous CO2 electromethanosynthesis and biodegradation of organic matters in a two-chamber microbial electrolysis cell. The 53rd Annual Conference of Japan Society on Water Environment (Lecture No.: 3-J-09-4), p. 373, 2019.3.7~9, University of Yamanashi, Kofu City, Japan.

[18]Zhen, G.Y.(Oral Presentation), Electro-conversion of carbon dioxide (CO₂) to low-carbon biomethane by microbial electrolysis cells platform. The 1st International Conference on Water Resources and Sustainability (ICWRS) & the 3rd International Conference on Alternative Fuels, Energy and Environment (ICAFEE): Future and Challenges (ICWRS & ICAFEE-2018), 28-31 Oct. 2018, Nanjing/Yixing, Jiangsu, China.

[17]Zhen, G.Y. (Poster presentation), Synergistically upgrading biomethane recovery from sewage sludge and food waste by mesophilic anaerobic co-digestion and the underlying stimulation mechanisms. The 1st International Conference on Water Resources and Sustainability (ICWRS) & the 3rd International Conference on Alternative Fuels, Energy and Environment (ICAFEE): Future and Challenges (ICWRS & ICAFEE-2018-2018), 28-31 Oct. 2018, Nanjing/Yixing, Jiangsu, China.

[16]Zhen, G.Y.(Poster presentation), Strengthening dewaterability of coke-oven plant oily sludge by Fe(II)-activated persulfate oxidation. The 1st International Conference on Water Resources and Sustainability (ICWRS) & the 3rd International Conference on Alternative Fuels, Energy and Environment (ICAFEE): Future and Challenges (ICWRS & ICAFEE), 28-31 Oct. 2018, Nanjing/Yixing, Jiangsu, China.

[15]Guangyin Zhen, Zhongxiang Zhi，Xue-Qin Lu, Takuro Kobayashi, Kaiqin Xu. In-situ Electrochemical Stimulation to Upgrade Co-digestion Behaviors of Sewage Sludge and Food Waste, The 52th Annual Conference of Japan Society on Water Environment, 2018.3.15~17，Hokkaido University, Hokkaido, Japan (awarded JSWE-IDEA Water Environment International Exchange，水環境国際招聘賞).

[14]Yong Hu, Guangyin Zhen, Kai-Qin Xu, Takuro Kobayashi (Poster), Effect of Lipid/TS ratio on anaerobic treatment of food waste under thermophilic condition.International Conference on Alternative Fuels & Energy, October 23-25, 2017 (selected for the best brainstorming awards,http://icaf-e.com/award.php).

[13] Zhen, G.Y.(Oral Presentation), Decorated carbon-based biocathode to improve electromethanosynthesis in a two-chamber microbial electrolysis cells (MECs), The 15th World Conference on Anaerobic Digestion (AD-15), Beijing, China, October 17-20, 2017.

[12] Zhen, G.Y. (Invited), Kobayashi, T., Xu, K. Promoting electromethanosynthesis in a two-chamber microbial electrolysis cells (MECs). “Green Energy”-Cooperation of the higher education sector for the development of green economy in the area of energetics-TAMOP-4.1.1. C-12/1/ KONV-2012-0017, May 28th-June 7th 2015, University of Pannonia, Veszpern, Hungary.

[11] Zhen, G.Y., Lu, X.Q., Kobayashi, T., Kumar, G., Xu, K. Hydrogen production from MSW (municipal solid waste) leachate in single-chamber microbial electrolysis cells (MECs). 2015 APEC Conference on Promoting Innovative and High Value-added Bio-product Production Technologies for Sustainable Development and 10th Asia Biohydrogen and Biorefinery Symposium (APEC-BPT/ ABBS-2015), Sep 21-24, 2015, Ken-Ting, Taiwan，China.

[10] 甄广印(Invited). 2016年同济大学国际青年学者论坛（环境领域分论坛）， 2016年5月18日-21日，上海同济大学环境科学与工程学院.

[9] 甄广印(Invited). 2016年华东师范大学国际青年学者论坛（生态与环境分论坛），2016年6月4-5日，上海华东师范大学生态与环境学院.

[8] Zhen, G.Y., Kobayashi, T., Xu, K. Bioelectrochemical treatment of liquid fraction of pressed municipal solid waste (LPW) for biohydrogen production in a single-chamber membrane-less microbial electrolysis cell. The 50th Annual Conference of Japan Society on Water Environment 2016, Tokusima, Japan (第50回日本水環境学会年会-2016-3月16-18).

[7] Zhen, G.Y., Lu, X.Q., Kobayashi, T., Xu, K. Insight into extracellular electron transfer for methane production in a two-chamber microbial electrolysis cells (MECs) containing a graphite biocathode. The 49th Annual Conference of Japan Society on Water Environment 2015(第49回日本水環境学会年会-2015). Kanazawa University, Kanazawa Japan, March 16-18 2015, pp. 343.

[6] Zhen, G.Y. (Chair of Session II: Antibiotics on the environment), Lu, X.Q., Li, Y.Y., Zhao, Y.C. Combined electrical-alkali pretreatment to increase the anaerobic hydrolysis rate of waste activated sludge during anaerobic digestion. International Symposium on Water Environment Problem-with Perspective of Global Safety in East Asian Countries, Part II. Sendai, Japan, March 21-22 2014, pp. 41-42.

[5] Zhao, Y.C., Jiang, J.C., Zhen, G.Y., Han, D., Lou, Z.Y., Zhang, H., Zhu, Y., A comparison of biogas generation and stabilization process in the landfills of refuse and modified sewage sludge, International conference: Biomass and organic waste as sustainable resources, ORBIT 2009, Beijing, China, 19-21.

[4] Liu, Y., Hojo, T. He, S.L., Zhen, G.Y., Li, Y.Y. Achievement and maintenance of partial nitritation by controlling DO concentration, Joint International Symposium Wastewater Treatment with Perspective of Anaerobic Bio-technology, China, 2014.

[3] Lu, X.Q., Zhen, G.Y., Adriana L.E., Li, Y.Y. Effect of cefalexin on mesophilic anaerobic digestion of waste activated sludge. The 48th Annual Conference of Japan Society on Water Environment 2014. Tohoku University, Sendai, Japan, March 17-19, 2014, pp. 79.

[2] 甄广印(特邀汇报)，赵由才. 污泥强化脱水与卫生填埋关键技术研究. 第七届中国污泥处理处置及资源综合利用技术论坛，2011年11月10-11日，浙江杭州(http://www.cneec.org.cn/en/news_show.asp?id=355).

[1] 甄广印(特邀汇报)，赵由才. 污泥强化脱水与卫生填埋关键技术. 第八届中国污泥处理处置及资源综合利用技术论坛，2012年5月17-18日，江苏苏州 (http://www.cneec.org.cn/news_show.asp?id=916).