近年主要科研项目

1.  科技部重点研发项目，2023YFC3709002，海陆交互带地下水污染诊断与风险管控技术体系，2023 年12 月 至 2026 年11 月，79.5万元，子课题负责人。

2.  科技部重点研发项目，2018YFC1802002，复合有机污染场地土壤高效强化化学氧化/还原协同修复技术，2019/01-2022/12， 65万元，子课题负责人。

3.  国家自然科学基金项目-山东省联合基金重点项目，U1806216，“黄河三角洲土壤污染生态修复机制研究”，2019/01-2022/12，333.76万元，主持人。

4.  国家自然科学基金面上项目，42377225，碳包覆零价铁的电子穿梭体效应及其调控微生物还原脱氯机制， 2024/01-2027/12，59万元，主持人。

5.  国家自然科学基金面上项目，41877372，新型稳定化生物炭-纳米铁复合材料的制备及其地球环境行为研究， 2019/01-2022/12，62万元，主持人。

6.  国家自然科学基金面上项目，41473070，土壤中典型石油烃降解基因的地理分异性及环境响应机制， 2015/01-2018/12，90万元，主持人。

7.  国家自然科学基金面上项目，31270544， 生物炭强化石油烃污染土壤生态修复及机理研究，2013/01-2016/12，79万元，主持人。

8.  天津市科技局中外联合研究中心项目，24PTLYHZ00190，中新低碳土壤地下水污染生物修复技术联合研究中心. 2024年10月至2026年9月，主持人。

9.  天津市科技局京津冀合作创新项目，23YFXTHZ00170，基于碳中和路径的雄安新区林下废弃物处理技术研究与示范. 2023年10月至2025年9月，主持人。

10. 天津市科技局应用基础研究重点项目，20JCZDJC00700，天然矿物制备氯代烃还原修复材料及与微生物联合作用机制研究，2020.4至2023.3，20万元，主持人。

11. 天津市科技局重点研发项目，21YFSNSN00240,典型有机复合污染场地修复技术和装备研发与示范, 2021/04-2024/3，65万元，主持人。

12. 中国石油化工股份有限公司项目，321093，石化场地挥发性氯代烃污染管控技术开发与应用，2021.1-2023.4，80万元，主持人。

共发表SCI论文220余篇，其中22篇为ESI高被引论文，H指数62。近年代表论文如下： 

[1] Guo, Saisai; Lyu,Honghong; Shi, Yinghao; Tang, Jingchun*.Overlooked risks of photoaging of nitrogenous microplastics with naturalorganic matter in water: Augmenting the formation of nitrogenous disinfectionby-products. Water Research, 2025, 274: 123085.

[2] Shi, Yinghao; Guo,Jiaming; Gao, Feilong; Wang, Dong; Lyu, Honghong; Tang, Jingchun*. Zero-valent iron-based materials for enhancedreductive removal of contaminants: From the trial-and-error synthesis torational design. Applied catalysis B-Environment and Energy, 2025, 365: 124901.

[3] Honghong Lyu, Xin Wang, Pin Li, Ping Yan, Jingchun Tang*. Mn/Co bimetalliccatalyst immobilized on N-doped biochar for enhanced photocatalytic degradationof sulfanilamide in water. Applied Catalysis B: Environment and Energy2024, 354: 124123.

[4] Wu, Han; Liu, Linan*;Zhuo, Yuguo; Ellam, Robert Mark; Yan, Keshuo; Liu, Juncheng; Tang, Jingchun*. Iron and siliconmodified biochar for enhancing cadmium removal from water: Unveiling the crucialrole of iron-induced silicon dissolution. Bioresource Technology, 2024, 401: 130745.

[5] Ri, Cholnam; Kim,Munchol; Mun, Hyokchol; Liu, Linan; Tang,Jingchun*. Unveiling the effect of different dissolved organic matter (DOM)on catalytic dechlorination of nFe/Ni particles: Corrosion and passivationeffect. Journal of Hazardous Materials, 2024, 469: 133901.

[6] Liu, Linan; Yang,Xinzuo; Ellam, Rob M.; Li, Qiang; Feng, Di; Song, Zhaoliang; Tang, Jingchun*. Evidence thatco-existing cadmium and microplastics have an antagonistic effect on greenhousegas emissions from paddy field soils. Journal of Hazardous Materials,2024, 467: 133696.

[7] Jin, Tianyue; Liu,Yaxuan; Lyu, Honghong; He, Yuhe; Sun, Hongwen; Tang, Jingchun*; Xing, Baoshan. Plastic takeaway food containersmay cause human intestinal damage in routine life usage: Microplasticsformation and cytotoxic effect. Journal of Hazardous Materials,2025, 475: 134866.

[8] Lyu, Honghong;Zhang, Hui; Dong, Jinrui; Shen, Boxiong; Cheng, Zi; Yu, Junhui; Li, Ruiyan;Shao, Ningning; Tang, Jingchun*. Pyrolysistemperature matters: Biochar-derived dissolved organic matter modulates agingbehavior and biotoxicity of microplastics. Water Research, 2024, 250: 121064.

[9] Guo, Jiaming; Wang, Dong; Shi, Yinghao; Lyu, Honghong*; Tang, Jingchun*. Minor chromiumpassivation of S-ZVI enhanced the long-term dechlorination performance oftrichlorethylene: Effects of corrosion and passivation on the reactivity andselectivity. Water Research, 2024, 249: 120973.

[10] Zhang, Wenzhu;Wang, Lan*; Liu, Qinglong; Lyu, Honghong; Tang,Jingchun*. Adsorption of PCBs on microplastics mitigated greenhouse gasemission by changing C/N metabolism in freshwater sediment. Journalof Cleaner Production, 2024, 434: 139883.

[11] Shi, Ruiying; Liu,Weitao; Lian, Yuhang; Wang, Xue; Men, Shuzhen; Zeb, Aurang; Wang, Qi; Wang,Jianling; Li, Jiantao; Zheng, Zeqi ; Zhou, Qixing; Tang, Jingchun; Sun, Yuebing; Wang, Fayuan; Xing, Baoshan. EnvironmentalScience & Technology, 2023, 58(2):1010-1021.

[12] Liu, Xiaomei;Ahmad, Shakeel; Ma, Jingkang; Wang, Dan; Tang,Jingchun*. Comparative study on the toxic effects of secondary nanoplasticsfrom biodegradable and conventional plastics on Streptomyces coelicolor M145. Journalof Hazardous Materials, 460: 132343.

[13] Ri, Cholnam; Li,Fengxiang; Mun, Hyokchol; Liu, Linan; Tang,Jingchun*. Impact of different zero valent iron-based particles onanaerobic microbial dechlorination of 2,4-dichlorophenol: Comparison ofdechlorination performance and the underlying mechanism. Journal of Hazardous Materials,2023, 458: 131881.

[14] Liu, Yaxuan; Jin,Tianyue; Wang, Lan; Tang, Jingchun*.Polystyrene micro and nanoplastics attenuated the bioavailability and toxiceffects of Perfluorooctane sulfonate (PFOS) on soybean (Glycine max) sprouts. Journalof Hazardous Materials. 2023, 448: 130911.

[15] Jin, Qianqian; Yu,Jianxin; Fan, Yinzheng; Zhan, Yuting; Tao, Danyang; Tang, Jingchun; He, Yuhe*. Release Behavior of Liquid CrystalMonomers from Waste Smartphone Screens: Occurrence, Distribution, andMechanistic Modeling. Environmental Science & Technology,2023, 57(28): 10319-10330.

[16] Gao, Feilong; Lyu,Honghong*; Ahmad, Shakeel; Xu, Siyu; Tang,Jingchun*. Enhanced reductive degradation of tetrabromobisphenol A bybiochar supported sulfidated nanoscale zero-valent iron: Selectivity and corereactivity. Applied Catalysis B: Environmental. 2023, 324: 122246.

[17] Xu Siyu; Wen Liangtao,Yu Chen; Li, Song; Tang, Jingchun*. Activationof peroxymonosulfate by MnFe2O4@BC composite for bisphenol A degradation: Thecoexisting of free-radical and non-radical pathways. Chemical Engineering Journal 2022,442: 136250.

[18] Shi, QY; Tang, JC*; Liu, XM; Liu, RT.Ultraviolet-induced photodegradation elevated the toxicity of polystyrenenanoplastics on human lung epithelial A549 cells. Environmental Science-NANO,2021, 8 (9): 2660-2675.

[19] Shi, QY; Tang, JC*; Liu, RT; Wang, L. Toxicityin vitro reveals potential impacts of microplastics and nanoplastics on humanhealth: A review. Critical Reviews in Environmental Science and Technology, 2021,52 (21): 3863-3895.

[20] Tang, JC; Zhao, BB; Lyu, HH*; Li, D. Developmentof a novel pyrite/biochar composite (BM-FeS2@BC) by ball milling for aqueousCr(VI) removal and its mechanisms. Journal of Hazardous Materials,2021, 413: 125415.

[21] He, J; Tang, JC*; Zhang, Z; Wang, L; Liu, QL; Liu,XM*. Magnetic ball-milled FeS@biochar as persulfate activator for degradationof tetracycline. Chemical Engineering Journal, 2021, 404: 126997

[22] Li, Song; Tang, Jingchun*; Liu, Qinglong; Liu, Xiaome;Gao, Bin. A novel stabilized carbon-coated nZVI as heterogeneous persulfatecatalyst for enhanced degradation of 4-chlorophenol. Environment International 2020,138: 105639.

[23] Liu, Xiaomei; Tang, Jingchun*; Song, Benru; Zhen,Meinan; Wang, Lan; Giesy, John P. Exposure to Al2O3 nanoparticles facilitatesconjugative transfer of antibiotic resistance genes from Escherichia coli toStreptomyces. Nanotoxicology 2019, 13(10): 1422-1436

[24] Lyu, Honghong; Tang, Jingchun*; Shen, Boxiong; Siddique,Tariq. Development of a novel chem-bio hybrid process using biochar supportednanoscale iron sulfide composite and Corynebacterium variabile HRJ4 forenhanced trichloroethylene dichlorination. Water Research 2018, 147: 132-141

[25] Lyu HH, Tang JC*, Huang Y, Gai LS, Zeng EY,Liber K, Gong, YY. Removal of hexavalent chromium from aqueous solutions by anovel biochar supported nanoscale iron sulfide composite. Chemical Engineering Journal2017, 322, 516-524.

其它成果见个人主页：https://env.nankai.edu.cn/2019/0612/c14180a177248/page.htm