报告人：吴江，南京师范大学环境学院教授、博士生导师，江苏特聘教授。《中国给水排水》青年编委；国际水协会中国青年委员会(IWA-YWP)委员，日本土木学会 (JSCE)、日本水环境学会(JSWE)会员。

报告题目：厌氧膜生物反应器耦合主流短程硝化-厌氧氨氧化工艺中对亚硝酸盐氧化菌的选择性抑制与厌氧氨氧化菌的原位富集

报告内容简介：在日本宫城县仙盐污水净化中心开展了中试规模厌氧膜生物反应器（AnMBR）与单级部分硝化–厌氧氨氧化（PN/A）低碳处理耦合工艺研究。通过原位游离氨（FA）与游离亚硝酸（FNA）交替冲击，结合低溶解氧（<0.5mg/L）运行策略，实现了对PN/A系统中亚硝酸氧化菌群落（NOB）的选择性抑制（靶向抑制），系统内氨氧化菌（AOB）与厌氧氨氧化菌（AnAOB）逐步形成稳定协同。该耦合生物处理工艺建立了高效除碳脱氮路径，在25℃下运行表现出稳定的碳氮去除能力与良好的污泥沉降性能。结果表明，在主流条件下连续运行中系统出水总氮（TN）浓度可维持在10 mg/L以下，实现了新型系统稳定启动与高效运行，为未来市政污水厂实现节能降耗与“双碳”目标提供了工艺概念与实践基础。

吴江

1989年4月生

工学博士，教授

入选国家海外引才专项计划，江苏特聘教授。主要从事有机污染物微生物处理技术工程性应用等研究。作为第一完成人结题多项日本国家级、特大排污企业有机污染物处理工程(试点)项目。《中国给水排水》青年编委，国际水协会(IWA) 、日本土木学会 (JSCE)、日本水环境学会(JSWE)会员。在Water Research、《用水と廃水》等环境工程专业期刊发表英、日、中文学术论文40余篇。为Chemical Engineering Journal、Bioresource Technology等十余部学术期刊审稿人。

联系方式

电子邮箱：wuj@nnu.edu.cn

办公室：南京师范大学仙林校区环境学院行远楼409室

通信地址：南京市栖霞区文苑路1号，210023

教育背景

2016.04-2019.03，日本东北大学 (Tohoku University)，土木与环境工程，工学博士学位

2014.04-2016.03，日本东北大学 (Tohoku University)，土木与环境工程，工学硕士学位

2009.09-2013.06，兰州理工大学，给水排水工程，工学学士学位

研究经历

2024.11-今，南京师范大学，环境学院，教授

2020.04-2024.10，日本国立环境研究所，资源循环领域，助理研究员(Research Associate)

2019.04-2020.03，日本东北大学 (Tohoku University)，博士后研究

主要研究方向

1. (厌氧)微生物处理工艺及其集成化技术

2. 生物质(市政污水、化工废水及有机固体废弃物等)低碳处理及生物能源再生

3. 微生物处理系统中的风险物质(新兴污染物、放射性金属等)归趋

* 除上述研究方向外，特别欢迎具有全生命周期评价(LCA)、碳足迹核算等研究经历或对多学科交叉融合研究模式抱有兴趣的同学报考本课题组硕、博士研究生。

近几年承担的国内外科研项目

7. 国家海外引才专项计划，2024-2027，主持

6. 江苏特聘教授项目，2024-2027，主持

5. 日本学术振兴会(JSPS)国家科学研究基金青年项目(科学研究費助成事業若手研究，24K17385)， In-situバイオ炭吸着による熱分解凝縮液の高速嫌気性処理プロセスの創出(原位生物炭吸附工艺耦合热解焦油的高速厌氧处理工艺)，2024-2027，主持

4. 日本环境省研究推进费项目子课题，1-2102，脱炭素化を目指した汚染バイオマスの先進的エネルギー変換技術システムの開発と実装シナリオの設計及び評価(面向脱碳化的放射性污染生物质能源转化系统开发及其实施方案设计与评估)，2022-2024，主持

3. 日本学术振兴会(JSPS)国家科学研究基金青年项目(科学研究費助成事業若手研究，21K14282)， 指定廃棄物の放射性Cs適性制御に資する溶出促進と嫌気性リーチングシステムの開発(放射性污染废弃物中铯在厌氧处理体系中的溶出控制优化)，2021-2023，主持

2. 日本环境省研究推进费项目子课题，1-2102，嫌気性膜分離法とアナモックスの融合デザインによる下水処理システムの実証研究(厌氧中空纤维膜反应器耦合一体式主流厌氧氨氧化工艺中试平台培育)，2019-2020，主持

1. 日本学术振兴会(JSPS)国家科学研究基金博士项目(17J00995)，新規資源循環型産業廃水の嫌気性後処理及びその脱硫技術(资源循环型工业废水厌氧脱硫后处理技术)， 2017-2019，主持

近期发表论文

30. Wu J, Hu Y, Ma H, Takahashi Y, Kobayashi T, Xu KQ, Kuramochi H: Biomass conversion and radiocaesium (Rad-Cs) leaching behaviors of radioactive grass in anaerobic wet fermentation systems: Effects of pretreatments. Water Research, Mar 15 2024; 252:121228.

29. Kong Z, Xue Y, Hao T, Zhang Y, Wu J, Chen H, Song L, Rong C, Li D, Pan Y, Li Y, Li YY. Carbon-neutral treatment of N, N-dimethylformamide-containing wastewater by up-flow anaerobic sludge blanket: CO2 reduction and bio-energy cleaner production. Journal of Cleaner Production. 2022, Dec; 20:134880.

28. Wu J, Kobayashi T, Li Y, Hu Y, Kuramochi H, LI YY. Competitive advantage changes between methanogenesis and sulfidogenesis in long-term UASB treatment of sulfate-rich ethanol-acetate wastewater. Journal of Water and Waste, 2022, 64 (8), 51-60.

27. Rong C, Luo Z, Wang T, Qin Y, Wu J, Guo Y, Hu Y, Kong Z, Hanaoka T, Sakemi S, Ito M, Kobayashi S, Kobayashi M, Li YY. Biomass retention and microbial segregation to offset the impacts of seasonal temperatures for a pilot-scale integrated fixed-film activated sludge partial nitritation-anammox (IFAS-PN/A) treating anaerobically pretreated municipal wastewater. Water Research. 2022, Oct 2; 225:119194.

26. Kong Z, Xue Y, Hao T, Zhang Y, Wu J, Chen H, Song L, Rong C, Li D, Pan Y, Li Y, Li YY. Carbon-neutral treatment of N, N-dimethylformamide-containing industrial wastewater by anaerobic membrane bioreactor (AnMBR): Bio-energy recovery and CO2 emission reduction. Bioresource Technology. May 28 2022; 358:127396.

25. Rong C, Wang T, Luo Z, Guo Y, Kong Z, Wu J, Qin Y, Hanaoka T, Sakemi S, Ito M, Kobayashi S, Kobayashi M, Li YY: Seasonal temperatures impact on the mass flows in the innovative integrated process of anaerobic membrane bioreactor and one-stage partial nitritation-anammox for the treatment of municipal wastewater. Bioresource Technology. April 2022; 349: 126864.

24. Ma H, Hu Y, Wu J, Kobayashi T, Xu KQ, Kuramochi H: Enhanced anaerobic digestion of tar solution from rice husk thermal gasification with hybrid upflow anaerobic sludge-biochar bed reactor. Bioresource Technology. Mar 2022; 347:126688.

23. Sanjaya EH, Chen Y, Guo Y, Wu J, Chen H, Din MFM, Li YY. The performance of simultaneous partial nitritation, anammox, denitrification, and COD oxidation (SNADCO) method in the treatment of digested effluent of fish processing wastewater. Bioresource Technology. Feb 2 2022; 346: 126622.

22. Kong Z, Li L, Wu J, Rong C, Wang T, Chen R, Sano D, Li YY. Unveiling the characterization and development of prokaryotic community during the start-up and long-term operation of a pilot-scale anaerobic membrane bioreactor for the treatment of real municipal wastewater. Science of the Total Environment. Mar 20 2022; 813: 126622.

21. Song J, Wu H, Yuan H, Wu J, Qi W, Lu J, Li W, Li YY. Reclamation of pharmaceutical wastewater by UAF, contact oxidation, and auto brush-cleaning aiding nano ZrO2 coated ceramic membrane MBR - An industrial-scale practice and functional microbial diversity. Journal of Water Process Engineering. April 2022, 46; 152643

20. Rong C, Luo Z, Wang T, Guo Y, Kong Z, Wu J, Ji J, Qin Y, Hanaoka T, Sakemi S, Ito M. Chemical oxygen demand and nitrogen transformation in a large pilot-scale plant with a combined submerged anaerobic membrane bioreactor and one-stage partial nitritation-anammox for treating mainstream wastewater at 25° C. Bioresource Technology. Dec 1 2021; 341:125840.

19. Wu J, Kong Z, Luo Z, Qin Y, Rong C, Wang T, Hanaoka T, Sakemi S, Ito M, Kobayashi S, Kobayashi M, Xu, KQ, Kobayashi T, Kubota K, Li YY. A successful start-up of an anaerobic membrane bioreactor (AnMBR) coupled mainstream partial nitritation-anammox (PN/A) system: A pilot-scale study on in-situ NOB elimination, AnAOB growth kinetics, and mainstream treatment performance. Water Research. Oct 21 2021; 207:117783.

18. Kong Z, Li L, Wu J, Wang T, Rong C, Luo Z, Pan Y, Li D, Li Y, Huang Y, Li YY. Evaluation of bio-energy recovery from the anaerobic treatment of municipal wastewater by a pilot-scale submerged anaerobic membrane bioreactor (AnMBR) at ambient temperature. Bioresource Technology. Nov 1 2021; 339:125551.

17. Hu Y, Shi C, Ma H, Wu J, Kobayashi T, Xu KQ. Biofilm formation enhancement in anaerobic treatment of high salinity wastewater: Effect of biochar/Fe addition. Journal of Environmental Chemical Engineering. Aug 1 2021;9 (4):105603.

16. Wu J, Jiang B, Kong Z, Yang C, Li L, Feng B, Luo Z, Xu KQ, Kobayashi T, Li YY. Improved stability of up-flow anaerobic sludge blanket reactor treating starch wastewater by pre-acidification: Impact on microbial community and metabolic dynamics. Bioresource Technology. Apr 1 2021; 326:124781.

15. Kong, Z, Wu, J, Rong, C, Wang, T, Li, L, Luo, Z, Ji J, Hanaoka T, Sakemi S, Ito M, Kobayashi S, Kobayashi M, Qin Y, Li YY. Sludge yield and degradation of suspended solids by a large pilot-scale anaerobic membrane bioreactor for the treatment of real municipal wastewater at 25° C. Science of the Total Environment. Mar10 2021; 759:143526.

14. Kong Z, Wu J, Rong C, Wang T, Li L, Luo Z, Ji J, Hanaoka T, Sakemi S, Ito M, Kobayashi S. Large pilot-scale submerged anaerobic membrane bioreactor for the treatment of municipal wastewater and biogas production at 25° C. Bioresource Technology. Jan 1 2021; 319:124123.

13. Wang C, Wu H, Wu J, Zhu B, Fan W, Lu T, Gao Y, Qi W, Niu Q. Promoted biodegradation of para-ester wastewater by electrostimulated ZVI assisting novel UBF/ceramic membrane MBR and microbial community. Journal of the Taiwan Institute of Chemical Engineers. Aug 1 2020; 113:285-92.

12. Wu J, Jiang B, Feng B, Li L, Moideen SN, Chen H, Mribet C, Li YY. Pre-acidification greatly improved granules physicochemical properties and operational stability of Upflow Anaerobic Sludge Blanket (UASB) reactor treating low-strength starch wastewater. Bioresource Technology. Apr 1 2020; 302:122810.

11. Kong Z, Li L, Wang T, Rong C, Xue Y, Zhang T, Wu J, Li YY. New insights into the cultivation of N, N-dimethylformamide-degrading methanogenic consortium: A long-term investigation on the variation of prokaryotic community inoculated with activated sludge. Environmental Research. Mar 1 2020;182:109060.

10. Li W, Niu Q, Wu J, Luan X, Qi W, Zhang Y, Li YY, Gao Y, Yang M. Enhanced anaerobic performance and SMD process in treatment of sulfate and organic S-rich TMBA manufacturing wastewater by micro-electric field–zero valent iron-UASB. Journal of Hazardous Materials. Nov 5 2019; 379:120695.

9. Wu J, Liu Q, Feng B, Kong Z, Jiang B, Li YY. Temperature effects on the methanogenesis enhancement and sulfidogenesis suppression in the UASB treatment of sulfate-rich methanol wastewater. International Biodeterioration & Biodegradation. Aug 1 2019; 142:182-190.

8. Chen H, Wu J, Liu B, Li YY, Yasui H. Competitive dynamics of anaerobes during long-term biological sulfate reduction process in a UASB reactor. Bioresource Technology. May 1 2019; 280:173-82.

7. Kong Z, Li L, Wu J, Zhang T, Li YY. Insights into the methanogenic degradation of N, N-dimethylformamide: The functional microorganisms and their ecological relationships. Bioresource Technology. Jan 1 2019; 271:37-47.

6. Wu J, Niu Q, Li L, Hu Y, Mribet C, Hojo T, Li YY. A gradual change between methanogenesis and sulfidogenesis during a long-term UASB treatment of sulfate-rich chemical wastewater. Science of the Total Environment. Sep 15 2018; 636:168-76.

5. Chen R, Nie Y, Kato H, Wu J, Utashiro T, Lu J, Yue S, Jiang H, Zhang L, Li YY. Methanogenic degradation of toilet-paper cellulose upon sewage treatment in an anaerobic membrane bioreactor at room temperature. Bioresource Technology. Mar 1 2017; 228:69-76.

4. Wang Q, Zhang B, Wang M, Wu J, Li Y, Gao Y, Li W, Jin Y. Synthetic lepidocrocite for phosphorous removal from reclaimed water: optimization using convex optimization method and successive adsorption in fixed bed column. Environmental Technology. Nov 1 2016; 37(21):2750-9.

3. Wu J, Hu Y, Hojo T, Li YY. Effect of Variation of Organic Matter Concentration on UASB Treatment of Sulfate Containing Ethanol/Acetic Acid-Based Chemical Industrial Wastewater. Journal of Water and Waste, 2016, 58 (3), 209-218.

2. Hu Y, Jing Z, Sudo Y, Niu Q, Du J, Wu J, Li YY. Effect of influent COD/SO42− ratios on UASB treatment of a synthetic sulfate-containing wastewater. Chemosphere. 2015; 130, 24-33.

1. Hu Y, Sudo Y, Wu J, Li YY. Performance of a Combined Anaerobic (UASB)-Aerobic (Activated Sludge) System in Synthetic Sulfate-Containing Wastewater Treatment. Journal of Water and Waste, 2015, 57 (8), 605-611.