姓  名: 彭云峰
职务/职称: 研究员
联系电话: (86)-010-62836632
电子邮件: pengyf@ibcas.ac.cn
个人网页: http://lvec.ibcas.ac.cn/rcdw/yjy/202002/t20200208_541941.html
课 题 组: 高寒生态格局与过程研究组
彭云峰,男,博士,研究员。

2006年于河北农业大学获学士学位,2012年于中国农业大学获博士学位,2010-2012年在美国密苏里大学进行联合培养。2013年进入中国科学院植物研究所从事博士后研究,2015年留所工作,先后任助理研究员、副研究员、研究员。2018年入选“中国科学院青年创新促进会”。以第一或通讯作者(含共同)在Global Change BiologyEcologyFunctional Ecology等生态学主流期刊发表学术论文20余篇。主持国家自然科学基金面上项目、青年基金项目、国家重点研发子课题等项目。

主要研究方向:

主要以青藏高原高寒草地为研究对象,基于大尺度观测、野外控制实验、meta分析、机器学习等手段,开展以下研究:(1)生态系统碳循环关键过程对全球变化的响应;(2)退化草地固碳潜力、机理及提升途径。

主持和参加的科研项目

  1. 国家自然科学基金面上项目,热融塌陷与未塌陷区土壤呼吸对增温的响应差异及其调控途径2023.01-2026.12,主持人
  2. 科技部国家重点研发计划项目我国冻土生态系统碳氮磷循环过程、机理及演化趋势2022.12-2027.11,子课题主持人
  3. 中国科学院院先导专项子课题,三江源高寒草甸退化机制和恢复的关键限制因子2020.11-2025.10,任务共同主持人
  4. 科技部“第二次青藏高原综合考察” 子子子专题,三江源西样带草地生态系统类型、结构、生产力变化及驱动机制,2019.11-2024.10,主持人
  5. 国家自然科学基金面上项目,高寒草原生态系统碳通量对不同氮水平的响应及其化学计量学机制,2018.01-2021.12主持人

代表性论文(#共同第一作者,*通讯作者)

2024

Zhou LN, Liu Y, Men MX, Peng ZP, Peng YF*, 2024. Widespread cooling of topsoil under nitrogen enrichment and implication for soil carbon flux. Science of the Total Environment, 912: 169480.

2023

Liu Y, Men MX, Peng ZP, Chen HYH, Yang YH, Peng YF*, 2023. Spatially explicit estimate of nitrogen effects on soil respiration across the globe. Global Change Biology, 29: 3591–3600.

彭云峰, 常锦峰, 赵霞, 石岳, 白宇轩, 李秦鲁, 姚世庭, 马文红, 方精云, 杨元合*, 2023.中国草地生态系统固碳能力及其提升途径. 中国科学基金, 37: 587-602.

2022

Li QL, Liu Y, Kou D, Peng YF*, Yang YH*, 2022. Substantial non-growing season carbon dioxide loss across Tibetan alpine permafrost region. Global Change Biology, 28: 5200–5210.

Liu Y, Men MX, Peng ZP, Houx JH, Peng YF*, 2022. Nitrogen availability determines ecosystem productivity in response to climate warming. Ecology, 103: e3823.

吴赞, 彭云峰*, 杨贵彪, 李秦鲁, 刘洋, 马黎华, 杨元合, 蒋先军*, 2022. 青藏高原高寒草地退化对土壤及微生物化学计量特征的影响. 植物生态学报, 46: 461–472.

2021

刘洋, 彭云峰*, 门明新, 彭正萍, 杨元合, 2021. 青藏高原高寒草原根系动态对氮添加的响应及其调控因素. 应用生态学报, 32: 3119–3126.

2020

Peng YF, Chen HYH, Yang YH*, 2020. Global pattern and drivers of nitrogen saturation threshold of grassland productivity. Functional Ecology, 34: 1979–1990.

2019

Peng YF, Wang GQ, Li F, Yang GB, Fang K, Liu L, Qin SQ, Zhang DY, Zhou GY, Fang HJ, Liu XJ, Liu CY, Yang YH*, 2019. Unimodal response of soil methane consumption to increasing nitrogen additions. Environmental Science & Technology, 53: 4150–4160.

Peng YF*, Peng ZP, Zeng XT, Houx JH, 2019. Effects of nitrogen-phosphorus imbalance on plant biomass production: A global perspective. Plant and Soil, 436: 245–252.

2018

Peng YF, Wang, GQ, Li F, Zhou G Y, Yang GB, Fang K, Liu L, Qin SQ, Zhang DY, Yang YH*, 2018. Soil temperature dynamics modulate N2O flux response to multiple nitrogen additions in an alpine steppe. Journal of Geophysical Research: Biogeosciences, 123: 3308–3319.

2017

Peng YF, Li F, Zhou GY, Fang K, Zhang DY, Li CB, Yang GB, Wang GQ, Wang J, Yang YH*, 2017. Linkages of plant stoichiometry to ecosystem production and carbon fluxes with increasing nitrogen inputs in an alpine steppe. Global Change Biology, 23: 5249–5259.

Peng YF, Guo DL, Yang YH*, 2017. Global patterns of root dynamics under nitrogen enrichment. Global Ecology and Biogeography, 26: 102–114.

Li F#, Peng YF#, Natali SM, Chen KL, Han TF, Yang GB, Ding JZ, Zhang DY, Wang GQ, Wang J, Yu JC, Liu FT, Yang YH*, 2017. Warming effects on permafrost ecosystem carbon fluxes are correlated with plant nutrients. Ecology, 98: 2851–2859.

Peng YF, Li F, Zhou GY, Fang K, Zhang DY, Li CB, Yang GB, Wang GQ, Wang J, Mohammat A, Yang YH*, 2017. Nonlinear response of soil respiration to increasing nitrogen additions in a Tibetan alpine steppe. Environmental Research Letters, 12: 024018.

2016及以前

Peng YF, Yang YH*, 2016. Allometric biomass partitioning under nitrogen enrichment: Evidence from manipulative experiments around the world. Scientific Reports, 6: 28918.

Peng YF, Zeng XT, Houx JH, Boardman DL, Li CJ, Fritschi FB*, 2016. Pre- and post-silking carbohydrate concentrations in maize ear-leaves and developing ears in response to nitrogen availability. Crop Science, 56: 1–10.

Peng YF, Li CJ, Fritschi FB*, 2014. Diurnal dynamics of maize leaf photosynthesis and carbohydrate concentrations in response to differential N availability. Environmental and Experimental Botany, 99: 18–27.

Peng YF, Yu P, Li XX, Li CJ*, 2013. Determination of the critical soil mineral nitrogen concentration for maximizing maize grain yield. Plant and Soil, 372: 41–51.

Peng YF, Li CJ, Fritschi FB*, 2013. Apoplastic infusion of sucrose into stem internodes during female flowering does not increase grain yield in maize plant grown under nitrogen limiting conditions. Physiologia Plantarum, 148: 470–480.

Peng YF, Li XX, Li CJ*, 2012. Temporal and spatial profiling of root growth revealed novel response of maize roots under various nitrogen supplies in the field. PLoS ONE, 7: e37726.

Peng YF#, Yu P#, Zhang Y, Sun G, Ning P, Li XX, Li CJ*, 2012. Temporal and spatial dynamics in root length density of field-grown maize and NPK in the soil profile. Field Crops Research, 115: 85–93.

Peng YF, Niu JF, Peng ZP, Zhang FS, Li CJ*, 2010. Shoot growth potential drives N uptake in maize plants and correlates with root growth in the soil. Field Crops Research, 115: 85–93.