王吉鹏
  • 王吉鹏
  • 电子邮件:wangjp@cib.ac.cn
  • 职  称: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

2024.04-今,中国科学院成都生物研究所,青年副研究员

2023.05-今,中国科学院成都生物研究所,助理研究员

2022.01-2023.04,成都理工大学,副教授

2018.09-2019.09,德国卡尔斯鲁厄理工学院,博士后

2016.09-2021.12,成都理工大学,讲师

2013.09,2016.07,中国科学院大学、成都山地灾害与环境研究所,博士

2010.09-2013.07,中国科学院大学、成都山地灾害与环境研究所,硕士

2006.09-2010.06,山东师范大学,学士


研究方向

根际过程与调控

获奖及荣誉

承担科研项目情况

    主持国家自然科学基金青年项目、四川省科技厅面上项目等3项,参与国家自然科学基金区域联合项目和重点项目各1项。

1. 国家自然科学基金青年项目,成土早期微生物碳需求对土壤有机磷矿化的驱动作用,25万元,2018.01-2020.12,主持

2. 四川省科技厅面上项目,攀枝花马家田尾矿库根际土壤自由固氮的限制因子和对钒积累的响应机制,10万元,2021.04-2023.03,主持

3. 西藏高原森林生态教育部重点实验室开放课题,藏东南亚热带常绿阔叶林不同树种根际土壤碳汇功能差异与调控机制研究,10万元,2024.03-2025.12,主持

4. 国家自然科学基金联合基金项目,氮沉降下川西高寒森林根际土壤碳汇功能变化及其调控机制,262万元,2024.01-2027.12,参与

5. 国家自然科学基金重点项目,贡嘎山东坡磷的生物地球化学循环过程与海拔分异,296万元,2017.01-2021.12,参与


代表论著

1. Wang,D.,Gao,W.,Wang,J.*,Yin,H.*,2024. Minimal impact of nitrogen addition on bacterial and fungal communities during fungal necromass decomposition in a subalpine coniferous plantation. Soil Biology and Biochemistry,109499.

2. Wang,J.,Zhao,Q.,Zhong,Y.,Ji,S.,Chen,G.,He,Q.,Wu,Y.,Bing,H.*,2023. Biological nitrogen fixation in barren soils of a high-vanadium region: Roles of carbon and vanadium. Soil Biology and Biochemistry 186,109163.

3. Wang,J.,Chen,G.,Ji,S.,Zhong,Y.,Zhao,Q.,He,Q.,Wu,Y.,Bing,H.*,2023. Close relationship between the gene abundance and activity of soil extracellular enzyme: Evidence from a vegetation restoration chronosequence. Soil Biology and Biochemistry 177,108929.

4. Wang,J.,Wu,Y.,Li,J.,He,Q.,Bing,H.*,2021. Soil enzyme stoichiometry is tightly linked to microbial community composition in successional ecosystems after glacier retreat. Soil Biology and Biochemistry 162,108429.

5. Wang,J.,Wu,Y.,Li,J.,He,Q.,Zhu,H.,Bing,H.*,2021. Energetic supply regulates heterotrophic nitrogen fixation along a glacial chronosequence. Soil Biology and Biochemistry,108150.

6. Wang,J.,He,Q.,Wu,Y.,Zhu,H.,Sun,H.,Zhou,J.,Wang,D.,Li,J.,Bing,H.*,2021. Effects of pioneer N2-fixing plants on the resource status and establishment of neighboring non-N2-fixing plants in a newly formed glacier floodplain,eastern Tibetan Plateau. Plant and Soil 458,261-276.

7. Wang,J.,Huang,S.,He,Q.,Bing,H.*,Chen,X.,Zhang,X.,Tian,X.,Zhou,J.,Wilcke,W.,Wu,Y.*,2020. Microplate fluorimetric assay of soil leucine aminopeptidase activity: alkalization is not needed before fluorescence reading. Biology and Fertility of Soils 56,281-285.

8. Wang,J.,Wu,Y.*,Zhou,J.,Bing,H.,Sun,H.,He,Q.,Li,J.,Wilcke,W.,2020b. Soil microbes become a major pool of biological phosphorus during the early stage of soil development with little evidence of competition for phosphorus with plants. Plant and Soil 446,259-274.

9. Wang,J.,Wu,Y.*,Zhou,J.,Bing,H.,Sun,H.,Luo,J.,Pu,S.,2020c. Air-drying changes the distribution of Hedley phosphorus pools in forest soils. Pedosphere 30,272-284.

10. Wang,J.,Wu,Y.*,Zhou,J.,Bing,H.,Sun,H.,2016. Carbon demand drives microbial mineralization of organic phosphorus during the early stage of soil development. Biology and Fertility of Soils 52,825-839.