学术成果
代表性论文(JCR一区)
1. Zan, F., Liang, Z.-S. JIANG, F*, Dai, J.*, Chen, G.; Effects of food waste addition on biofilm formation and sulfide production in a gravity sewer. Water Res. 2019, 157, 74-82
2. Liang, Z.-S.; Zhang, L.; Wu, D.; Chen, G.-H.; JIANG, F*. Systematic evaluation of a dynamic sewer process model for prediction of odor formation and mitigation in large-scale pressurized sewers in Hong Kong. Water Res. 2019, 154, 94-103
3. Sun, J.; Hong, Y.; Guo, J.; Yang, J.; Huang, D.; Lin, Z.; JIANG, F*. Arsenite removal without thioarsenite formation in a sulfidogenic system driven by sulfur reducing bacteria under acidic conditions. Water Res. 2019, 151, 362-370
4. Zhang, W.; JIANG, F. Membrane fouling in aerobic granular sludge (AGS)-membrane bioreactor (MBR): effect of AGS size. Water Res. 2019,157,445-453
5. Huang H, Ekama G A, Biswal B K, Dai J., JIANG F., Chen G.-h., Wu D.*. A new sulfidogenic oxic-settling anaerobic (SOSA) process: The effects of sulfur-cycle bioaugmentation on the operational performance, sludge properties and microbial communities. Water Res., 2019 (in press)
6. Qian, J., Zhang, M., Niu, J., Fu, X., Pei, X., Chang, X., Wei, L., Liu, R., Chen, G.-H. and JIANG, F*. Roles of sulfite and internal recirculation on organic compound removal and the microbial community structure of a sulfur cycle-driven biological wastewater treatment process. Chemosphere. 2019, 226, 825-833
7. Wang, J.-t.; Zhang, L.; Kang, Y.; Chen, G.; JIANG, F.* Long-term feeding of elemental sulfur alters microbial community structure and eliminates mercury methylation potential in SRB-abundant activated sludge. Environ. Sci. Technol. 2018, 52, 8, 4746-4753
8. Sun, J.; Li, L.; Zhou, G.; Wang, X.; Zhang, L.; Liu, Y.; Yang, J.; Lü, X.; JIANG, F.* Biological sulfur reduction to generate H2S as a reducing agent to achieve simultaneous catalytic removal of SO2 and NO and sulfur recovery from flue gas. Environ. Sci. Technol. 2018, 52, 8, 4754-4762
9. Zhang, L.; Zhang, Z.-f.; Sun, R.-r.; Chen, G.-H.; JIANG, F.* Self-accelerating sulfur reduction via polysulfide to realize a high-rate sulfidogenic reactor for wastewater treatment. Water Res. 2018, 130: 161-167.
10. Sun, R.-r.; Zhang, L.; Zhang, Z.-f.; Chen, G.-H.; JIANG, F.* Realizing high-rate sulfur reduction under sulfate-rich conditions in a biological sulfide production system to treat metal-laden wastewater deficient in organic matter. Water Res. 2018, 131: 239-245
11. Zhang, L.; Lin, X.; Zhang, Z.; Chen, G.-H.; JIANG, F.* Elemental sulfur as an electron acceptor for organic matter removal in a new high-rate anaerobic biological wastewater treatment process. Chem. Eng. J. 2018, 331, 16-22.
12. Zhang, Y.; Zhang, L.; Li, L.; Chen, G.-H.; JIANG, F.* A novel elemental sulfur reduction and sulfide oxidation integrated process for wastewater treatment and sulfur recycling. Chem. Eng. J. 2018, 342, 438-445.
13. Zan, F.; Dai, J.*; Hong, Y.; Wong, M.; Jiang, F.*; Chen, G. The characteristics of household food waste in Hong Kong and their implications for sewage quality and energy recovery. Waste Manage. 2018, 74:63-73
14. Wang, B.; Wu, D.; Ekama, G. A.; Tsui, T.-H.; JIANG, F.; Chen, G.-H. Characterization of a new continuous gas-mixing sulfidogenic anaerobic bioreactor: Hydrodynamics and sludge granulation. Water Res. 2018, 135, 251-261.
15. Qiu, Y.-Y.; Guo, J.-H.; Zhang, L.; Chen, G.-H.; JIANG, F.* A high-rate sulfidogenic process based on elemental sulfur reduction: Cost-effectiveness evaluation and microbial community analysis. Biochem. Eng. J. 2017, 128, 26-32.
16. Liang, S.; Zhang, L.; JIANG, F.* Indirect sulfur reduction via polysulfide contributes to serious odor problem in a sewer receiving nitrate dosage. Water Res. 2016, 100, 421-428.
17. JIANG, F.*; Zhang, L.; Peng, G. L.; Liang, S. Y.; Qian, J.; Wei, L.; Chen, G. H. A novel approach to realize SANI process in freshwater sewage treatment--Use of wet flue gas desulfurization waste streams as sulfur source. Water Res. 2013, 47, (15), 5773-82.
18. JIANG, F.; Leung, D. H. W.; Li, S. Y.; Chen, G. H.; Okabe, S.; van Loosdrecht, M. C. M. A biofilm model for prediction of pollutant transformation in sewers. Water Res. 2009, 43, (13), 3187-3198.
发明专利
1. 一种适用于硫化氢催化还原脱硫脱硝工艺的Ce基复合催化剂及其制备方法,中国发明专利,2017101472762.9
2. 一种适用于硫化氢催化还原脱硫脱硝工艺的Fe-Ce基复合催化剂及其制备方法,中国发明专利,201710142763.3
3. 使硫磺转化为聚合硫化物以提高其生物可利用性的方法,中国发明专利,201610377070.8
4. 排水管道中硫化氢产生量的预测方法,中国发明专利,201610136984.5. 已授权
5. 一种以硫化氢为还原剂的燃煤烟气同步脱硫脱硝工艺,中国发明专利,201510598948.6
6. 一种协同烟气脱硫和污水有机物降解及脱氮的方法与装置,中国发明专利,201510194353.4
7. 一种适用于下水道有害气体原位控制的装置 及其吸附剂制备方法,中国发明专利,201510201525.6. 已授权
8. 一种以单质硫为介质实现污泥减量的污水处理工艺,中国发明专利,ZL201310103765.3,已授权。
9. 一种用于膜生物反应器的双层结构的平板膜元件,中国发明专利, 申请号: 201310302966.6.
10. 利用硫化合物作为电子载体的生物废水处理及回用以减少污泥产量,日本发明专利,JP 2014501609A
11. Method for wastewater treatment by urine separation, seawater addition, and nitrification and in-sewer denitrification, 美国发明专利US 20140116939 A1
12. Biological wastewater treatment and reuse utilizing sulfur compounds as electron carrier to minimize sludge production, 美国发明专利US 20130256223 A1
13. 一种结合有尿液分离、海水添加、硝化及下水道内反硝化的污水处理方法,中国发明专利,201280025344.7
14. 以硫化合物作为电子载体以实现污泥产量最小化的污水生物处理及回用,中国发明专利,ZL201180057987.5