个人信息
Personal Information
联系方式
Contact Information
个人简介
Personal Profile
中国农业科学院作物科学研究所,二级研究员,作物耕作与生态创新团队首席。1999年毕业于南京农业大学,获得农学博士学位,2001年至2003年在美国North Carolina State University,开展土壤生态博士后合作研究。2006年入选教育部“新世纪优秀人才”,2018年江苏省“双创”领军人才。现为农业农村部“东北黑土地保护性耕作专家指导组”、“全球重要农业文化遗产专家委员会”和“秸秆综合利用专家指导组”成员,中国耕作制度学会副理事长、中国立体农业分会秘书长,The Crop Journal副主编,世界银行和联合国粮农组织咨询专家。研究方向:农田生态与耕作制度。主要贡献:工作以来一直从事农田生态与耕作制度的科研与教学及技术推广工作,在农田生态系统对气候变化的响应与适应、农田土壤碳氮循环及其环境效应、保护性耕作丰产增效技术等领域取得了较好的研究进展。先后主持国家重点基础研究计划(973计划)课题、“十二五”国家科技支撑计划项目、“十三五”国家重点研发计划项目、国家现代农业产业技术体系岗位科学家任务、国家自然科学基金面上项目等科研任务,理论成果发表在Nature和Science Advances等期刊上,技术研发获得省部级科技一等奖和二等奖共7项。
稻作区土壤培肥与丰产增效耕作技术,6900(万,2016.01-2020.06,国家“十三五”重点研发项目,项目首席
传统用地养地技术挖掘与创新,350(万),2017.01-2025.12,国家绿肥产业技术体系,岗位科学家
[1] Zhang L.,Zheng J., ……, ZhangW.*, 2015. Integrative effects of soil tillageand straw management on crop yields and greenhouse gas emissions in arice–wheat cropping system. European Journal of Agronomy, 63: 47–54.
[2] Sun Y., HuangS., ......, ZhangW.*, 2015. Differences in fertilization impactson organic carbon content and stability in a paddy and an upland soil insubtropical China. Plant and Soil, 397:189–200.
[3] Huang S., SunY., ......, ZhangW.*, 2015. Interactive effects of temperatureand moisture on CO2 and CH4 production in a paddy soilunder long-term different fertilization regimes. Biology andFertility of Soils, DOI10.1007/s00374-015-1075-3.
[4] Feng J., LiF., ……, ZhangW*. 2016. Integrated assessment of the impact ofenhanced-efficiency nitrogen fertilizer on N2O emission and cropyield. Agriculture, Ecosystems and Environment, 231: 218–228.
[5] Zhu X., ZhangJ., ......, ZhangW.*, 2016. Dense planting with less basalnitrogen fertilization might benefit rice cropping for high yield with lessenvironmental impacts. European Journal of Agronomy, 75: 50–59.
[6] Zheng C.,Zhang J., ……, ZhangW*. 2017. Nighttime warming increases winter-sownwheat yield across major Chinese cropping regions. Field CropsResearch, 214: 202–210.
[7] Huang X.,Chen C., ......, ZhangW*. 2017. Quantification for carbon footprint ofagricultural inputs of grains cultivation in China since 1978. Journal of CleanerProduction, 142: 1629-1637.
[8] Jiang Y., vanGroenigen K, .…, ZhangW.*. 2017. Higher yields and lower methaneemissions with new rice cultivars. Global Change Biology, 23:4728–4738.
[9] Jiang Y.,Qian H., Wang L., ……, ZhangW*. 2018. Limited potential of harvest indeximprovement to reduce methane emissions from rice paddies. Global ChangeBiology. DOI: 10.1111/gcb.14529.
[10] Jiang Y.,Qian H., ……, ZhangW*. 2019. Acclimation of methane emissions from ricepaddy fields in response to straw incorporation. Science Advances, 2019;5: eaau9038
[11] Zhang Y.,Jiang Y., ……, ZhangW*. 2019. Contribution of rice variety renewal andagronomic innovations to yield improvement and greenhouse gas mitigation inChina. Environmental Research Letters,doi.org/10.1088/1748-326/ab488d.
[12] Song Z.,Feng X., ……, ZhangW*. 2019. Optimized agronomic management as adouble-win option for higher maize productivity and less global warmingintensity: A case study of Northeastern China. Advances in Agronomy, doi.org/10.1016/bs.agron.2019.04.002.
[13] Chen C., vanGroenigen K.J., ……, ZhangW*. 2020. Global warming and shifts in croppingsystems together reduce China's rice production. Global FoodSecurity,doi.org/10.1016/j.gfs.2020.100359.
[14] Qian H., HuangS., ……, ZhangW*. 2020. Lower-than-expected CH4 emissionsfrom rice paddies with rising CO2 concentrations. Global ChangeBiology, DOI: 10.1111/gcb.14984.
[15] Qian H., JinY., ……, ZhangW*. 2021. Acclimation of CH4 emissions frompaddy soil to atmospheric CO2 enrichment over time in agrowth-chamber experiment. The Crop Journal, https://doi.org/10.1016/j.cj.2021.03.017
文件上传中...
