生态学博士,1991年生,中国科学院亚热带农业生态研究所副研究员,美国罗格斯大学土壤系高级访问学者,担任高影响力SCI期刊iMeta(IF2023 23.8)执行副主编、Front. Microbiol.客座副主编、Agronomy客座主编、Soil Sci. &Environ科学编辑、Eco-Environ. & Health青年编委等学术兼职。主要从事微生物生态与调控、根际微生物互作与元素生物地球化学循环等方面研究。先后主持国家自然科学基金项目、国家重点研发计划子课题、广东省自然科学基金面上项目、广东省高校重点领域专项、广东省高校青年创新人才项目等20多项课题。共发表SCI收录论文56篇,近5年发表SCI收录论文42篇,包括Microbiome、J. Hazard. Mater.、Environ. Int.、Sci. Total. Environ.、Environ. Sci-Nano、Environ. Pollut.等环境领域知名期刊,主编/副主编教材3部,授权国家发明专利5项。获得华夏建设科学技术三等奖1项(省部级)、地理信息科技进步二等奖1项(省部级)、广东省环境保护科学技术一等奖1项、金粤自然资源科学技术二等奖2项、广东省环境技术进步二等奖3项、全国商业联合会科学技术三等奖1项、广东省农业技术推广二等奖1项。担任广东省室内环境卫生行业协会标准化委员会委员、广州市环境科学学会理事,广东省农村科技特派员团队负责人,广州市农村科技特派员团队负责人,另担任国家自然科学基金委函评专家、广东省基础与应用基础研究基金委员会项目评审专家、广州市科技局项目评审专家、中南大学、中山大学等高校研究生论文盲审专家库专家。
【1】长沙市自然科学基金重点项目:微塑料介导的稻田氮元素微生物转化过程中N2O的释放机制(kq2502110),2025.01-2026.12.
【2】科技部国家重点研发计划子课题:南方丘陵山区农业面源调查监测评估系统性方案及示范(2024YFD1701304-04),2024.12-2027.11.
【3】科技部国家重点研发计划子课题:大气碳氮硫跨介质迁移转化过程和机制(2024YFC3711903-04),2024.12-2027.11.
【4】国家自然科学基金青年项目:微塑料介导的油麦菜根际土壤难溶态镉活化机制研究(42007375),2021.01-2023.12.
【5】广东省自然科学基金面上项目:耐镉内生菌菌剂的制备及其在超累积植物修复镉污染农田中的协同应用(2023A1515012532),2023.01-2025.12.
【6】广东省普通高校重点领域专项:微塑料介导水稻根际土中铁氮耦合过程影响镉的活化机制(2023ZDZX4016),2023.10-2026.10.
【9】广州市科技计划项目-创新环境专题:梅州茶园土壤酸化阻控与增产提质改良技术研究与应用(2023E04J1236),2023.04-2025.03
【8】广东省科技厅乡村振兴省级团队项目:淡水鲈鱼养殖水质环境(耐药基因)调控与应用示范,2021.12-2024.11
【10】广东省重点建设学科科研能力提升项目子课题:香蕉根际土壤环境健康与土壤环境因子的关系研究((2022ZDJS019),2022.01-2025.12.
【7】广东省普通高校青年创新人才项目:多组学研究微塑料介导油麦菜根际土壤镉活化的分子机制(2020KQNCX030),2020.12-2022.04.
【11】环境污染过程与基准教育部重点实验室开放基金:根际促生菌剂协同超累积植物修复镉污染土壤机制研究(2021b06),2021.10-2023.10.
【12】粤港澳环境质量协同创新联合实验室开放基金:土壤-作物体系中不同基团包被微塑料的迁移行为及其累积毒性效应(GHML2021-301),2020.12-2022.04.
【13】广东省农业环境综合治理重点实验室开放基金:根际缓释促生菌肥的研发及其在龙葵修复镉污染农田中的协同应用(2020B1212060048),2022.01-2023.12
[1] Chang,Y.,Lin,L.,Shen,J.,Lin,Z.,Deng,X.,Sun,W.,Wu,X.,Wang,Y.,Li,Y*.,Xu,Z*. (2025). Enhanced nitrogen fixation and Cd passivation in rhizosphere soil by biochar-loaded nitrogen-fixing bacteria: Chemisorption and microbial mechanism. Journal of Hazardous Materials,481,136588. (中国科学院一区TOP,IF 12.2)
[2] Xu,Z.,Deng,X.,Lin,Z.,Wang,L.,Lin,L.,Wu,X.,Wang,Y.,Li,H.,Shen,J*.,Sun,W. (2025). Microplastics in agricultural soil: Unveiling their role in shaping soil properties and driving greenhouse gas emissions. Science of The Total Environment,958,177875. (中国科学院一区TOP,IF 8.2)
[3] Shao,M.,Chen,H.,Huang,A.,Zheng,L.,Li,C.,Qin,D.,Sun,Y.,Lin,Z.,Fu,G.,Cheng,Y.,Li,Y.,Dong,Z.,Cheng,P.,Pramono,H.,Yu,G.,Xu,Z*.,Miao,S*.,D.Hyde,K. (2025). Modulation of rhizosphere microbiota by Bacillus subtilis R31 enhances long-term suppression of banana fusarium wilt. iMetaOmics. Accepted.
[4] Wang,Y.,Sun,X*.,Cao,Y.,Xu,Z*.,Sun,H.,Guan,X.,Ghani,M.,Zheng,L,Li,B.,Huang,D.,Sun,W*. (2025). Identification of hydrogen oxidation coupled with antimonate reduction,a novel antimony biogeochemical cycling,in two contrasting antimony contaminated environments. Microbiome. Accepted. (中国科学院一区TOP,IF 13.8)
[5] Zhong,C.,Lin,Z.,Hu,W.,& Xu,Z*. (2025). Evaluating the long-term stability of iron oxide-adsorbed cadmium: The role of organic acids and microbial agents in re-mobilization dynamics. Journal of Environmental Chemical Engineering,115502.(中国科学院二区,IF 7.4)
[6] Li,H.,Lin,L.,Liu,H.,Deng,X.,Wang,L.,Kuang,Y.,Lin,Z.,Liu,P.,Wang,Y.,Xu,Z*. (2024). Simultaneous exposure to nanoplastics and cadmium mitigates microalgae cellular toxicity: Insights from molecular simulation and metabolomics. Environment International,186,108633.(中国科学院一区TOP,IF 10.03)
[7] Gu,J.,Guo,F.,Lin,L.,Zhang,J.,Sun,W.,Riaz,M.,Liang,H.,Duan,D.,Deng,X.,Lin,Z.,Wang,Y.,Zhong,Y., Xu,Z*, (2023). Microbiological mechanism for “production while remediating” in Cd-contaminated paddy fields: A field experiment. Science of the Total Environment,885,163896. (中国科学院一区TOP,IF 8.2)
[8] Wu,X.,Lin,L.,Lin,Z.,Deng,X.,Li,W.,He,T.,Zhang,J.,Wang,Y.,Chen,L.,Lei,Z.,Liu,C.,Xu,Z*. (2024). Influencing mechanisms of microplastics existence on soil heavy metals accumulated by plants. Science of The Total Environment,171878.(中国科学院一区TOP,IF 8.2)
[9] Lin,L.,Wu,X.,Deng,X.,Lin,Z.,Liu,C.,Zhang,J.,He,T.,Yi,Y.,Liu,H.,Wang,Y.,Sun,W.,Xu,Z*. (2024). Mechanisms of low cadmium accumulation in crops: A comprehensive overview from rhizosphere soil to edible parts. Environmental Research,245,118054.(中国科学院二区TOP,IF 7.7)
[10] Xu,Z.,Shen,J.,Lin,L.,Chen,J.,Wang,L.,Deng,X.,Wu,X.,Lin,Z.,Zhang,Y.,Yu,R.,Zhang,J.,Zhang,Y.*,Wang C*. (2023). Exposure to irregular microplastic shed from baby bottles activates the ROS/NLRP3/Caspase-1 signaling pathway,causing intestinal inflammation. Environment International,181,108296.(中国科学院一区TOP,IF 10.03)
[11] Zhou,H.,Wang,J.,Jiang,H.,Cai,Z.,Tang,G.,Ding,S.,Liu,S.,Xu,Z*. (2023). Distribution fractions and potential ecological risk assessment of heavy metals in mangrove sediments of the Greater Bay Area. Environmental Science and Pollution Research,30(16),45859-45871. (中国科学院三区,IF 5.8)
[12] Xu,Z*.,Zhang,Y.,Wang,L.,Liu,C.,Sun,W.,Wang,Y.,Long,S..,He,X.,Lin,Z.,Liang,J.,& Zhang,J. (2022). Rhizobacteria communities reshaped by red mud based passivators is vital for reducing soil Cd accumulation in edible amaranth. Science of the Total Environment,826,154002.(中国科学院一区TOP,IF 8.2)
[13] Xu,Z*.,Lu,Z.,Zhang,L.,Fan,H.,Wang,Y. (2021). Red mud based passivator reduced Cd accumulation in edible amaranth by influencing root organic matter metabolism and soil aggregate distribution. Environmental pollution,275,116543.(中国科学院二区TOP,IF 7.6)
[14] Xu,Z.,Zhang,Y.,Zhong,Y.,Wang,L.,Liu,C.,Chen,A.,Jiang,S.,Sun,W.,Yu,G.,Li,Y.,Li,C.,Wang,Y.,Yu,R.,Zhang,L*. (2023). Dysregulation of gut health in zebrafish by differentially charged nanoplastic exposure: An integrated analysis of histopathology,immunology,and microbial informatics. Environmental Science: Nano,10(3),933-947.(中国科学院二区,IF 5.8)
[15] Xu,Z.,Wu,X.,Zhang,J.,Cheng,P.,Xu,Z.,Sun,W.,Zhong,Y.,Wang,Y.,Yu,G*.,Liu,H. (2022). Microplastics existence intensified bloom of antibiotic resistance in livestock feces transformed by black soldier fly. Environmental Pollution,317,120845.(中国科学院二区TOP,IF 7.6)
[16] Duan,D.,Zhang,Y.,Li,J.,Huang,L.,Xu,Z*.,Zhang,Y.,Sun,W.,Wang,Q.,Ruan,R. (2023). Synthesis of nanocrystalline cellulose induced hierarchical porous ZSM-5 for catalytic conversion of low-density polyethylene. Fuel,331,125757.(中国科学院一区TOP,IF 6.8)
[17] Duan,D.,Feng,Z.,Zhang,Y.,Zhou,T., Xu,Z*. (2022). Corncob pyrolysis: Improvement in hydrocarbon group types distribution of bio oil from co-catalysis over HZSM-5 and activated carbon. Waste Management,141,8-15.(中国科学院一区TOP,IF 7.1)
[18] Xu,Z*.,Zhang,Y.,Lin,L.,Wang,L.,Sun,W.,Liu,C.,Yu,G.,Yu,J.,Lv,Y.,Chen,J.,Chen,X.,Fu,L.,Wang,Y. (2022). Toxic effects of microplastics in plants depend more by their surface functional groups than just accumulation contents. Science of the Total Environment,833,155097.(中国科学院一区TOP,IF 8.2)
[19] Xu,Z.,Wang,J.,Li,W.,Wang,Y.,He,T.,Wang,F.,Lu,Z.,Li,Q*. (2021). Nitrogen fertilizer affects rhizosphere Cd re-mobilization by mediating gene AmALM2 and AmALMT7 expression in edible amaranth roots. Journal of Hazardous Materials,418,126310.(中国科学院一区TOP,IF12.2)
[20] Xu,Z*,Wang,D.,Tang,W.,Wang,L.,Li,Q.,Lu,Z.,Liu,H.,Zhong,Y.,He,T.,Guo,S. (2020). Phytoremediation of cadmium-polluted soil assisted by D-gluconate-enhanced Enterobacter cloacae colonization in the Solanum nigrum L. rhizosphere. Science of The Total Environment,732,139265.(中国科学院一区TOP,IF 8.2)