- 吴恒
- 电子邮件:wuheng@cib.ac.cn
- 职 称:青年副研究员
- 学 历:博士研究生
- 通讯地址:四川省成都市天府新区群贤南街23号
- 邮 编:610213
个人简历
博士毕业于西北农林科技大学,获得西北农林科技大学优秀博士论文、全国宝钢奖学金等,主要从事低碳/高难污水处理与农业固废高值化利用生物技术研究。主持四川省自然科学基金、中国科学院成都生物所自主部署项目等在内多项国家级、省部级科研项目。以第一作者\通讯作者在Advanced Science(热点论文+高被引论文,Frontispiece插图)、Microbiome(热点论文+高被引论文)、Chemical Engineering Journal、Journal of Cleaner Production等期刊发表SCI\中文论文近30篇,H指数17。担任Scientific Reports(中科院三区,影响因子3.9)编委,担任中文核心期刊《中国有色冶金》、《内蒙古农业大学学报》、英文期刊Collagen and Leather(IF 9.2)青年编委。担任Water Research、Bioresource Technology、 Energy、Agricultural Water Management、Journal of Cleaner Production、Journal of Environmental Management、Environmental Research、Journal of Water Process Engineering、Process Safety and Environmental Protection、 Environmental Technology Innovation等近30本期刊审稿人。
研究方向
污水与固废资源化生物技术
社会任职
担任Scientific Reports(中科院三区,IF 3.9)编委
担任中文核心期刊《中国有色冶金》、《内蒙古农业大学学报》、英文期刊Collagen and Leather(IF 9.2)青年编委
担任Water Research、Bioresource Technology、 Energy、Agricultural Water Management、Journal of Cleaner Production、Journal of Environmental Management、Environmental Research、Journal of Water Process Engineering、Process Safety and Environmental Protection、 Environmental Technology Innovation等近30本期刊审稿人
获奖及荣誉
1.西北农林科技大学优秀博士论文
2.宝钢优秀学生奖学金
承担科研项目情况
代表性项目
1. “稳态自驱动”共生菌群级联协同调控高盐有机废水抗逆性产己酸及机制研究,四川省自然科学基金-青年基金,主持,10万元
2. “促进水解产酸-抑制产甲烷”协同菌群驱动厌氧消化定向产丙酸及机制研究,博士后科学基金面上资助项目,主持,8万元
3. 肠衣废水“梯级驱动”资源回收与固液分离技术,企业委托,主持,100万元
4. 氧浓度调控作用下膜曝气生物膜富集HN-AD菌体系氮代谢机制研究,重庆市自然科学基金面上项目,参研
5. 固体碳源富集HN-AD菌体系碳代谢与氮转化机制,国家自然科学基金-青年基金,参研
代表论著
[1]Wu H. Li A., Zhang H., et al. (2024) Microbial mechanisms for higher hydrogen production in anaerobic digestion at constant temperature versus gradient heating. Microbiome, 12:170.微生物领域顶刊,2025、2026热点论文、高被引论文
[2]Wu H. Zhang H., Yan R., et al. (2024) Limosilactobacillus regulating microbial communities to overcome the hydrolysis bottleneck with efficient one-step co-production of H2 and CH4. Advanced Science, 2406119.综合领域顶刊,2025、2026热点论文、高被引论文、Frontispiece插图
[3]Wu, H., Dong, T., L i A., et al. (2025). An innovative strategy for overcoming ultra-High ammonia nitrogen inhibition on anaerobic methanogenesis via stepwise domestication. Microbiome, 13:223.微生物领域顶刊
[4]Wu, H., Zhang, H., Dong, T., et al. (2025). Overcoming extreme ammonia inhibition on methanogenesis by artificially constructing a synergistically community with acidogenic bacteria and hydrogenotrophic archaea. Advanced Science, 2502743.综合领域顶刊
[5] Wu, H., Yang, T., Zhang, M., et al. (2023). Effect of HRT on nitrogen removal from low carbon source wastewater enhanced by slurry and its mechanism. Chemical Engineering Journal, 477, 147159.
[6]Yan R.1, Wu, H.1, Yang, X., et al. (2023). Soil decreases N2O emission and increases TN content during combined composting of wheat straw and cow manure by inhibiting denitrification. Chemical Engineering Journal, 477, 147306.(共同一作)
[7]Wu, H., Zheng J., Wang J., et al. (2023). The clean nitrogen removal process based on solid carbon sources: Research progress and outlook. Journal of Cleaner Production, 383, 135508.
[8]Wu, H., Zhan G., Zhang H., et al. (2026). Stress-tolerant heterotrophic nitrification-aerobic denitrification strains: nitrogen removal performance, applications, and mechanisms. Bioresource Technology, 442, 133768.
[9]Wu, H., Zhan G., Zhang H., et al. (2026). Inhibition of acetogenesis and methanogenesis by inoculating successively ammonia nitrogen-inhibited anaerobic fermentation residues for rapid-efficient propionate accumulation. Bioresource Technology, 443, 133873.
[10] Wu, H., Li, A., Gao, S., et al. (2023). The performance, mechanism and greenhouse gas emission potential of nitrogen removal technology for low carbon source wastewater. Science of the Total Environment, 903, 166491.
[11]Wu, H., Xing, Z., Zhang G. (2024). Dissolved oxygen drives heterotrophic microorganism succession to regulate low carbon source wastewater treatment enhanced by slurry. Journal of Environmental Management, 366,121804.
[12]Wu, H., Zhang, Q., Chen, X. et al. (2022). The influence mechanism of DO on the microbial community and carbon source metabolism in two solid carbon source systems. Environmental Research, 206, 112410.
[13]Wu, H., Zhang, Q., Chen, X., et al. (2021). Efficiency and microbial diversity of aeration solid-phase denitrification process bioaugmented with HN-AD bacteria for the treatment of low C/N wastewater. Environmental Research, 202, 111786.
[14]Wu, H., Li, A., Wang, J., et al. (2022). A novel electrochemical sensor based on autotropic and heterotrophic nitrifying biofilm for trichloroacetic acid toxicity monitoring. Environmental Research, 210, 112985.
[15]Wu, H., YangT., Huang B., et al. (2024). The operating temperature affects the efficiency and pathogenic risk of wastewater treatment enhanced by slurry. Process Safety and Environmental Protection, 188, 1306-1317.
[16]Wu, H., Zhang, Q., Chen, X., et al. (2021). Effect of HRT and BDPs types on nitrogen removal and microbial community of solid carbon source SND process treating low carbon/nitrogen domestic wastewater. Journal of Water Process Engineering, 40, 101854.
[17]Wu, H., Yan R., Li A., et al. (2024). Efffcient treatment of alcohol wastewater and its potential pollutant control strategies. Journal of Water Process Engineering, 58, 104882.
[18]Wu, H., Cui, M., Yang, N. et al. (2022). Aerobic biocathodes with potential regulation for ammonia oxidation with concomitant cathodic oxygen reduction and their microbial communities. Bioelectrochemistry, 144, 107997.
[19]Wu, H., Cui, M., Yang, X., et al. (2022). Visual signal sensor coupling to nitrification for sustainable monitoring of trichloroacetaldehyde and the response mechanisms. Bioelectrochemistry, 146, 108142.
[20]Shi, Y., Gou, F., Chen, A., Xing, Z.*, Zhang, Q., Wu, H.*, et al. (2024). Influence and mechanism of typical transition metal ions on the denitrification performance of heterotrophic nitrification-aerobic denitrification bacteria. Environmental Research, 258, 119460.(共同通讯)
