袁超磊 - 南开大学 - 环境科学与工程学院

个人简介

教育背景 2012.9—2015.7，澳大利亚阿德雷德大学，理学博士（土壤学） 2009.9—2012.6，中国科学院生态环境研究中心，理学硕士（环境科学） 2005.9—2009.7，中国农业大学，理学学士（生态学）科研教学经历 2018.12至今，南开大学，副教授 2016.2-2018.11，广东省生态环境技术研究所，助理研究员/博士后科研项目 2020.1-2023.12，铁硫还原—氧化耦合体系对镉赋存状态及移动性的影响机制，国家自然科学基金委员会面上项目，41977273，61万，主持 2019.4-2022.3，环境因子对土壤微生物砷还原的影响机制，天津市自然科学基金青年项目，19JCQNJC07700，6万，主持 2017.1-2019.12，水稻土硫酸盐还原耦合铁还原钝化镉的化学和微生物机理，国家自然科学基金委员会青年科学基金项目，20万，主持 2016.8-2018.5，异化铁还原耦合镉行为的微生物及化学机制，中国博士后科学基金面上项目（一类），8万，主持 2016.5-2018.5，“珠江人才计划”海外青年人才引进计划（博士后资助项目），广东省人力资源和社会保障厅，60万，主持专利： (1)郭岩彬; 吴文良; 李军慧; 夏娜; 袁超磊; 牟成香; 王开勇; 周华宁; 李金云. 荧光假单胞菌CKD18及其应用. 授权公告号 CN 101709217 B. (2)郭岩彬; 吴文良; 位婉; 孟凡乔; 周华宁; 焦子伟; 牟成香; 袁超磊. 一种球状节杆菌CNA9及其应用. 授权公告号 CN 102021129 B.

研究领域

土壤生物地球化学、土壤污染修复

近期论文

查看导师新发文章（温馨提示：请注意重名现象，建议点开原文通过作者单位确认）

(1)Yuan, C., Li, Q., Sun, Z., Sun, H., 2021. Effects of natural organic matter on cadmium mobility in paddy soil: A review. Journal of Environmental Sciences 104, 204-215. (2)Yuan, C., Na, S., Li, F., Hu, H., 2020. Impact of sulfate and iron oxide on bacterial community dynamics in paddy soil under alternate watering conditions. Journal of Hazardous Materials, 124417. DOI: 10.1016/j.jhazmat.2020.124417 (3)Yuan, C., Qiao, J., Li, F., Zhang, X., Du, Y., Hu, M., Sun, W., 2020. Community dynamics of As(V)-reducing and As(III)-oxidizing genes during a wet–dry cycle in paddy soil amended with organic matter, gypsum, or iron oxide. Journal of Hazardous Materials 393, 122485. DOI:10.1016/j.jhazmat.2020.122485 (4)Yuan, C.-L., Zhang, L.-M., Wang, J.-T., Teng, W.-K., Hu, H.-W., Shen, J.-P., He, J.-Z., 2020. Limited effects of depth (0-80cm) on communities of archaea, bacteria and fungi in paddy soil profiles. European Journal of Soil Science. DOI: 10.1111/ejss.12921 (5)Yuan, C., Li, F., Cao, W., Yang, Z., Hu, M., Sun, W., 2019. Cadmium solubility in paddy soil amended with organic matter, sulfate, and iron oxide in alternative watering conditions. Journal of Hazardous Materials 378, 120672. DOI: 10.1016/j.jhazmat.2019.05.065 (6)Yuan, C.-L., Zhang, L.-M., Wang, J.-T., Hu, H.-W., Shen, J.-P., Cao, P., He, J.-Z., 2019. Distributions and environmental drivers of archaea and bacteria in paddy soils. Journal of Soils and Sediments 19, 23-37. (7)Yuan, C., Liu, T., Li, F., Liu, C., Yu, H., Sun, W., Huang, W., 2018. Microbial iron reduction as a method for immobilization of a low concentration of dissolved cadmium. Journal of Environmental Management 217, 747-753. (8)Yuan, C.-L., Zhang, L.-M., Hu, H.-W., Wang, J.-T., Shen, J.-P., He, J.-Z., 2018. The biogeography of fungal communities in paddy soils is mainly driven by geographic distance. Journal of Soils and Sediments 18, 1795-1805. (9)Yuan, C., Li, F., Han, R., Liu, T., Sun, W., Huang, W., 2017. Effects of Cd on reductive transformation of lepidocrocite by Shewanella oneidensis MR-1. Acta Geochimica 36, 479-481. (10) Yuan, C., Mosley, L.M., Fitzpatrick, R., Marschner, P., 2016. Organic matter addition can prevent acidification during oxidation of sandy hypersulfidic and hyposulfidic material: Effect of application form, rate and C/N ratio. Geoderma 276, 26-32. (11) Yuan, C., Fitzpatrick, R., Mosley, L.M., Marschner, P., 2015. Sulfate reduction in sulfuric material after re-flooding: Effectiveness of organic carbon addition and pH increase depends on soil properties. Journal of Hazardous Materials 298, 138-145. (12) Yuan, C., Mosley, L.M., Fitzpatrick, R., Marschner, P., 2015. Amount of organic matter required to induce sulfate reduction in sulfuric material after re-flooding is affected by soil nitrate concentration. Journal of Environmental Management151, 437-442. (13) Yuan, C.-L., Mou, C.-X., Wu, W.-L., Guo, Y.-B., 2011. Effect of different fertilization treatments on indole-3-acetic acid producing bacteria in soil. Journal of Soils and Sediments 11, 322-329. (14) 袁超磊, 贺纪正, 沈菊培, 戴宇, 张丽梅. 2013. 一个红壤剖面微生物群落的焦磷酸测序法研究. 土壤学报 50, 138-149. (15) Wang, X., Li, F., Yuan, C., Li, B., Liu, T., Liu, C., Du, Y., Liu, C., 2019. The translocation of antimony in soil-rice system with comparisons to arsenic: Alleviation of their accumulation in rice by simultaneous use of Fe(II) and NO3−. Science of the Total Environment 650, 633-641. (16) Mosley, L.M., Biswas, T.K., Cook, F.J., Marschner, P., Palmer, D., Shand, P., Yuan, C., Fitzpatrick, R.W., 2017. Prolonged recovery of acid sulfate soils with sulfuric materials following severe drought: causes and implications. Geoderma 308, 312-320. (17) Hu, H.-W., Zhang, L.-M., Yuan, C.-L., Zheng, Y., Wang, J.-T., Chen, D., He, J.-Z., 2015. The large-scale distribution of ammonia oxidizers in paddy soils is driven by soil pH, geographic distance, and climatic factors. Frontiers in Microbiology6: 938. (18) Hu, H.-W., Zhang, L.-M., Yuan, C.-L., He, J.-Z., 2013. Contrasting Euryarchaeota communities between upland and paddy soils exhibited similar pH-impacted biogeographic patterns. Soil Biology and Biochemistry64, 18-27. (19) 贺纪正, 袁超磊, 沈菊培, 张丽梅. 2012. 土壤宏基因组学研究方法与进展. 土壤学报49, 155-164. (20) Shen, X.-Y., Zhang, L.-M., Shen, J.-P., Li, L.-H., Yuan, C.-L., He, J.-Z., 2011. Nitrogen loading levels affect abundance and composition of soil ammonia oxidizing prokaryotes in semiarid temperate grassland. Journal of Soils and Sediments 11, 1243-1252.

学术兼职

2020.11至今，《Geoderma》副主编