尊龙凯时 - 人生就是搏!-z6com

课题组长-何红波

何红波,研究员,博士生导师
地  址:沈阳市沈河区文化路72号 尊龙凯时人生就是搏z6com沈阳应用生态研究所
电  话:024-83970376
E-mail:hehongbo@iae.ac.cn
教育背景
1989-1992 南开大学化学系 学士
1992-1995 南开大学化学系 硕士
2003-2005 尊龙凯时人生就是搏z6com沈阳应用生态研究所 博士
工作经历
1995-2002 沈阳理工大学理学院 讲师
2005-2010 尊龙凯时人生就是搏z6com沈阳应用生态研究所 副研究员
2011-至今 尊龙凯时人生就是搏z6com沈阳应用生态研究所 研究员
研究方向
土壤碳氮转化生物化学过程及土壤养分供应评价与调控
农田生态系统土壤环境质量及调控
主持及参加课题
国家重点研发计划,2022YFD1500302、黑土地土壤有机质衰减过程及阻控的革新性农艺技术、2022/11-2027/10、330万元、在研、主持;
尊龙凯时人生就是搏z6com先导A类项目,XDA28010301、土壤有机质衰减的阻控原理与提升的耕作培肥技术、2021/09-2026/07、573.35万元、在研、主持;
辽宁省“兴辽英才计划”,XLYC2008015、辽宁省现代保护性耕作研发与应用创新团队、2020/01-2023/12、100万元、在研、主持;
国家自然科学基金面上项目,41977025、农田黑土植物和微生物组分积累的分异特征及其碳输入的调控机制、2020/01-2023/12、直接经费61万元、在研、主持;
国家重点研发计划,2017YFD0200105、旱地农田肥料氮去向、损失过程与调控原理、2017/01-2020/12、530万元、已结题、主持;
尊龙凯时人生就是搏z6com交叉创新团队,全球变化对土壤-植物系统光合碳截获过程的影响、2016/01-2019/12、100万元、已结题、主持;
国家自然科学基金面上项目,41571237、温带森林土壤有机碳矿化温度敏感性的海拔效应及控制机制研究、2016/01-2019/12、直接经费70万元、已结题、主持;
尊龙凯时人生就是搏z6com战略性先导科技专项(B类)专题,XDB15040201、微生物参与策略表征及群落功能的定量评价技术、2014/07-2019/06、150万元、已结题、主持;
国家自然科学基金面上项目,41271251、光合碳和外源氮素在土壤-植物系统的分配和稳定机制及其碳氮偶联效应、2013/01-2016/12、75万元、已结题、主持;
国家自然科学基金重点项目,41130524、农田土壤有机氮组分的更新过程及驱动机制研究、2012/01-2016/12、280万元、已结题、参加;
国家重点基础研究发展计划(973计划)专题,2011CB403202、天然森林和草地的碳截获潜力估算、2011/01-2015/08、80万元、已结题、主持;
国家自然科学基金面上项目,41071161、作物光合碳向农田土壤有机质关键组分的转化及其对CO2升高的响应、2011/01-2013/12、40万元、已结题、主持;
尊龙凯时人生就是搏z6com战略性先导科技专项(A类)专题,XDA05050501、东北农田土壤固碳潜力与速率研究、2011/01-2015/12、465万元、已结题、参加;
尊龙凯时人生就是搏z6com知识创新工程重要方向课题,KZCX2-YW-T06、东北农田生态系统碳、氮循环及耦合机制研究、2010/03-2012/12,90万元、已结题、参加;
国家重点基础研究发展计划(973计划)专题,2009CB118607、作物高产高效的土壤条件与定向调控、2009/01-2013/08、50万元、结题、主持;
国家自然科学基金面上项目,40871149、肥料氮素向土壤氨基酸的转化及稳定化机制研究、2009/01-2011/12、43万元、已结题、主持;
"十一五"国家科技支撑计划课题,2007BAD89B02、农田养分循环调控与肥料减量化技术研究、2008/01-2010/12、619万元、已结题、参加;
尊龙凯时人生就是搏z6com"东北之春"人才培养计划课题,CMP田间(环境)效应及国产化研究、2007/12-2011/12、30万元、已结题、主持;
尊龙凯时人生就是搏z6com沈阳应用生态研究所海外留学基金,07HWLX11S4、东北平原现代保护性耕作技术研究和示范、2007/01-2009/12、12万元、已结题、主持;
国家重点基础研究发展计划(973计划)专题,2005CB121104、乙草胺的转化、传递与积累过程与作物产地环境安全(前两年);农业有机废弃物资源再循环与作物产地环境安全(后三年)、2006/01-2010/12、38.6万元、已结题、主持;
国家自然科学基金面上项目,40471068、土壤氨基酸手性异构体转化更新探讨、2005/01-2007/12、33万元、已结题、参加。
代表性文章
Ma, X.S., Zhang, W., Zhang, X.C., Bao, X.L., Xie, H.T., Li, J., He, H.B., Liang, C., Zhang, X.D. 2022.Dynamics of microbial necromass in response to reduced fertilizer application mediated by crop residue return. Soil Biology and Biochemistry, 108512. 
Wang X.X., Zhang W., Liu Y., Jia Z.J., Li H., Yang Y.F., Wang D.M., He H.B., Zhang X.D. 2021. Identification of microbial strategies for labile substrate utilization at phylogenetic classification using a microcosm approach. Soil Biology & Biochemistry, 153,107970.
Zhao Y., Liang C., Shao S., Li J., Xie H.T., Zhang W., Chen F.S., He H.B., Zhang X.D. 2021. Interactive effects of elevated CO2 and nitrogen fertilization levels on photosynthesized carbon allocation in a temperate spring wheat and soil system. Pedosphere, 31(1): 191–203.
Zhang W., Dong S.H., Nie M., Liang C., Zhang X.C., He, H.B. Zhang X.D. 2021. Effect of temperature on microbial residue dynamics in a temperate farmland soil. Canadian Journal of soil science, 101: 1-4.
Zhang W., Zhang X.C., Bai E., Cui Y.H., He H.B., Zhang X.D. 2020. The strategy of microbial utilization of the deposited N in a temperate forest soil. Biology and Fertility of Soils, 56(3), 359-367.
Hu G.Q., Zhao Y., Liu X., Zhou F., Zhang W., Shao S., He H.B., Zhang X.D. 2020. Comparing microbial transformation of maize residue‐N and fertilizer‐N in soil using amino sugar‐specific 15N analysis. European Journal of Soil Science, 71(2), 252-264. 
Li X.B., Li Z.A., Zhang X.D., Xi L.L., Zhang W.X., Ma Q.Q., He H.B. 2020. Disentangling immobilization of nitrate by fungi and bacteria in soil to plant residue amendment. Geoderma, 374,114450. 
Wang X.X., Zhang W., Zhou F., Liu Y., He H.B., Zhang X.D. 2020. Distinct regulation of microbial processes in the immobilization of labile carbon in different soils. Soil Biology & Biochemistry, 142, 107723.
Li J., Zhang X.C., Luo J.F., Lindsey S., Zhou F., Xie H.T., Li Y., Zhu P., Wang L.C., Shi Y.L., He H.B., Zhang X.D. 2020. Differential accumulation of microbial necromass and plant lignin in synthetic versus organic fertilizer-amended soil.Soil Biology and Biochemistry, 149, 107967. 
Liu X., Zhou F., Hu G.Q., Shao S., He H.B., Zhang W., Zhang X.D., Li L.J. 2019. Dynamic contribution of microbial residues to soil organic matter accumulation influenced by maize straw mulching. Geoderma, 333:35-42. 
Li J., Yang H., Zhou F., Zhang X.C., Luo J.F., Li Y., Lindsey S., Shi Y.L., He H.B., Zhang X.D. 2019. Effects of maize residue return rate on nitrogen transformations and gaseous losses in an arable soil. Agricultural Water Management, 211:132-141. 
Ding X.L., Zhang B., Filley R.T., Tian C.J., Zhang X.D., He H.B. 2019. Changes of microbial residues after wetland cultivation and restoration. Biology and Fertility of Soils, 55:405–409.
Li L.D., Wilsona B.C., He H.B., Zhang X.D., Zhou F., Schaeffer M.S. 2019. Physical, biochemical, and microbial controls on amino sugar accumulationin soils under long-term cover cropping and no-tillage farming. Soil Biology and Biochemistry,135:369-378.
Jing Y.L., Wang Y., Liu S.R., Zhang X.D., Wang Q.K., Liu K., Yin Y., Deng J.F. 2019. Interactive effects of soil warming, throughfall reduction, and root exclusion on soil microbial community and residues in warm-temperate oak forests. Applied Soil Ecology, 142:52-58.
Zhao Y., Shao S., Schaeffer S.M. Bao X.L., Zhang W., Zhu B., He H.B., Zhang X.D. 2019. Methodological clarification for estimating the input of plant-derived carbon in soils under elevated CO2 based on a 13C-enriched CO2 labeling experiment. Plant and Soil, 440: 569–580.
Li X.B., He H.B., Zhang X.D., Yan X.Y., Cai Z.C., Zhang J.B., Li Z.A., Ma Q.Q. 2019. Distinct responses of soil fungal and bacterial nitrate immobilization to land conversion from forest to agriculture. Soil Biology & Biochemistry, 134: 81-89.
Ding X.L., Chen S.Y., Zhang B., Liang C., He H.B., Horwathd W.R.2019. Warming increases microbial residue contribution to soil organic carbon in an alpine meadow. Soil Biology & Biochemistry, 135:13-19.
Shao P.S., He H.B., Zhang X.D., Xie H.T.,Bao X.L., Liang C. 2018. Responses of microbial residues to simulated climate change in a semiarid grassland. Science of the Total Environment, 688:1286-1291.
Shao S., Zhao Y., Zhang W., Hu G.Q., Xie H.T., Yan J.H., Han S.J., He H.B., Zhang X.D. 2017.Linkage of microbial residue dynamics with soil organic carbon accumulation during subtropical forest succession. Soil Biology & Biochemistry, 114:114-120.
Zhang W., Liang C., Kao-Kniffin J., Xie H.T., He H.B., Zhang X.D.2017.Effects of drying and wetting cycles on the transformations of extraneous inorganic N to soil microbial residues. Scientific report, 7:9477.
Hu G.Q., He H.B., Zhang W., Zhao J.S., Cui J.H., Li B., Zhang X.D. 2016. The transformation and renewal of soil amino acids induced by the availability of extraneous C and N. Soil Biology & Biochemistry, 96: 86-96. 
Bai Z., Liang C., Bode S., Huygens D., Boeckx P. 2016. Phospholipid 13C stable isotopic probing during decomposition of wheat residues. Applied Soil Ecology 98: 65-74. 
Zhang W., Cui Y.H., Lu X.K., Bai E., He H.B., Xie H.T., Liang C., Zhang X.D. 2016. High nitrogen deposition decreases the contribution of fungal residues to soil carbon pools in a tropical forest ecosystem. Soil Biology & Biochemistry, 97: 211-214. 
Liu X., Hu G.Q., He H.B., Liang C., Zhang W., Bai Z., Wu Y.Y., Lin G.F., Zhang X.D. 2016. Linking microbial immobilization of fertilizer nitrogen to in situ turnover of soil microbial residues in an agro-ecosystem. Agriculture, Ecosystems & Environment, 229: 40-47. 
Tian Q.X., He H.B., Cheng W.X., Bai Z., Wang Y., Zhang X.D. 2016. Factors controlling soil organic carbon stability along a temperate forest altitudinal gradient. Scientific Report, 6: 18783. 
专利
何红波,张旭东. 2006. 气质联机测定土壤氨基酸手性异构体同位素富集速率. 授权专利号:ZL200610155816.7
李奕,何红波,张旭东,张威,袁磊,卢佳.2022.一种设有高效清选结构的全喂入收获机.授权专利号:ZL202123267543.4

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