学习经历

1984.9~1988.7, 兰州大学生物系，获理学学士学位(植物学)

1988.9~1991.6, 中国科学院植物研究所，获理学硕士学位(生态学)

1996.9~1998.8, 中国科学院植物研究所，获理学博士学位(生态学)

1999.7~2002.8, 哈佛大学进化与生物学系博士后(生物学)

2007.10~2008.1, 瑞士苏黎世大学，The Swiss National Science Foundation Research Fellow

教育工作

1991.6~1999.11 中国科学院植物研究所，实习研究员，助理研究员，副研究员

2002.8~2008.7 北京大学生态学系，副教授

2007.1~北京大学生态学系副主任

2008.8~ 北京大学生态学系，教授

2009.3~ 西北高原生物研究所百人计划

学术任职

《植物生态学报》编委，2004~

《生物多样性》编委，2009~

Journal of Plant Ecology (Oxford University Press，SCI), Associate editor, 2008~

Journal of Plant Research (Springer,SCI), Editorial Board Member, 2007~2014

Frontiers in Ecology and the Environment (ESA journal,SCI), Associate editor, 2007~2014

中国植物学会植物生态学专业委员会委员，2009~

中国植物学会学术委员会委员，2009~

研究方向

1. 植物生理生态学

2. 生态系统生态学

3. 青藏高原生态学

4. 生物多样性的生态系统功能

当前研究领域

1、生态系统生态学:主要围绕陆地生态系统的碳循环和氮循环, 采用实验的手段，研究全球气候变化影响下生态系统过程的反应。近期的研究重点是:降雨格局的改变和氮沉降如何影响温带草地、人工林C、N循环的主要过程。

2、植物功能属性:通过野外植物主要生态属性的测定，结合室内植物的解剖结构的分析，在大尺度、多生态系统类型上探讨植物生态属性的变化规律和控制因子。

3、地下生态学:通过典型生态系统地下过程的调查，探讨生态系统地上和地下部分的关联，重点探讨植物地上部分得到的规律性是否可以应用到地下。

4、生物多样性的生态系统功能:结合实验途径和野外调查，研究生物多样性的生态系统功能，特别是在C, N经济(C, N economy) 中的作用。主要的实验系统是草原生态系统。

研究项目

1、国家重点基础研究发展规划(973计划):中国陆地生态系统碳循环及其驱动机制研究(2002-2007)，专题主持

2、国家自然科学基金重大研究计划重点项目:我国温带草地碳库分布、动态与气候控制(2003-2006)，专题主持

3、国家自然科学基金委 "创新群体":环境生物地球化学研究(2004-2006)成员

4、国家自然科学基金重大研究计划面上项目(90411004):温带草地根系生态学的实验研究:个体、种群和功能属性的关联(2005-2007)，主持

5、国家自然科学基金委面上项目(30670322):青藏高原极端环境条件下植物叶功能属性特征及环境的修饰作用(2007-2009)，主持

6、中日韩A3前瞻计划项目(Asia 3 Foresight Program):Quantifying and predicting terrestrial carbon sinks in East Asia: toward a network of climate change research，A3 3+2(2007-2012)，参加

7、国家科技支撑计划(2007BAC06B00):藏北高寒草甸区生态稳定性维持技术研究与示范(专题)(2007.9-2010.12)，主持

8、国家自然科学基金委面上项目(30870381):我国主要温带草地优势植物叶片、根系和土壤C:N:P化学计量学的关联(2009-2011)，主持

9、欧盟项目(BACCARA):Biodiversity And Climate Change，A Risk Analysis(2009-2011)，专题3

10、科技部国际合作(Sino-EU 0916):Risk analysis of biodiversity change:a case study in a subtropical forest，China(2009-2012)，主持

11、基金委创新群体项目(31021001):中国陆地植被的时空格局与生态功能(2011-2013)，核心成员

12、"全球变化研究国家重大科学研究计划"项目(2010CB950600):中国陆地生态系统碳源汇特征及其全球意义(2010-2013)，研究骨干

13、国家杰出青年科学基金(31025005):植物功能属性与化学计量生态学 (2011-2014)，主持

14、全球变化研究国家重大科学研究计划项目(2014CB954004)(973)"土壤系统碳动态、机制及其对全球变化的响应"(2014-2018)，首席科学家

1998年，中科院地奥奖学金"一等奖, 博士论文"神农架地区米心水青冈林和锐齿槲栎林的格局和过程"

2003年，教育部自然科学一等奖:中国陆地生态系统碳循环与植被生产力的研究，第3完成人^[3]

2004年，国家自然科学二等奖:中国陆地生态系统生产力和碳循环的研究，第5完成人

2006年，北京大学"保洁"奖^[4]

2007年，Sino-Swiss Science and Technology Cooperation Research Fellowship, Swiss Federal Institute of Technology (ETH Zurich), Swiss National Science Foundation

2007年，北京大学优秀班主任三等奖^[5]

2010年，"国家杰出青年科学基金" 获得者

2014年，北京大学"保洁"奖

Jing X, Sanders NJ, Shi Y, Chu HY, Classen AT, Zhao K, Chen LT, Jiang YX, He J-S* 2015.The links between ecosystem multifunctionality and above- and belowground biodiversity are mediated by climate.Nature Communications6: 8159.

Song WM, Wang H, Wang GS, Chen LT, Jin ZN, Zhuang QL, He J-S*. 2015.Methane emissions from an alpine wetland on the Tibetan Plateau: Neglected but vital contribution of non-growing season.Journal of Geophysical Research-Biogeosciences: doi:10.1002/2015JG003043.

Jin ZN, Zhuang QL, He J-S, Zhu XD, Song WM 2015.Net exchanges of methane and carbon dioxide on the Qinghai-Tibetan Plateau from 1979 to 2100.Environmental Research Letters: doi:10.1088/1748-9326/10/8/085007.

Niu KC, He J-S, Zhang ST, Lechowicz MJ 2015.Grazing increases functional richness but not functional divergence in Tibetan alpine meadow plant communities.Biodiversity and Conservation: doi: 10.1007/s10531-015-0960-2.

Chen LT, Flynn DFB, Zhang XW, Gao XL, Lin L, Luo J, Zhao CM* 2015.Divergent patterns of foliar δ13C and δ15N in Quercus aquifolioides with an altitudinal transect on the Tibetan Plateau: an integrated study based on multiple key leaf functional traits.Journal of Plant Ecology8: 303-312.

Chen LT, Flynn DFB, Jing X, Kühn P, Scholten T, He J-S 2015.A comparison of two methods for quantifying soil organic carbon of alpine grasslands on the Tibetan Plateau.PLoS ONE10: e0126372.

Mi ZR, Huang YY, Gan HJ,Zhou WJ, Flynn DFB, He J-S* 2015.Leaf P increase outpaces leaf N in an Inner Mongolia grassland over 27 years. Biology Letters 11: 20140981.

Ding S, Xu Y, Wang Y, He Y,Hou J, Chen L,He J-S 2015.Distributions of glycerol dialkyl glycerol tetraethers in surface soils ofQinghai–Tibetan Plateau: implications of GDGT-based proxies in cold and dryregions. Biogeosciences Discussion 12: 481-513.

Zhang ZJ,Yan YJ,Tian Y, LiJS, He J-S, Tang ZY* 2015.Distribution and conservation of orchid species richness in China. Biological Conservation 181: 64-72.

Eichenberg D, Trogisch S,Huang YY, He J-S, Bruelheide H 2014.Shifts in community leaf functional traits are related to litter decompositionalong a secondary forest succession series in subtropical China. Journal of Plant Ecology DOI:10.1093/jpe/rtu021: .

Wang YH, Liu HY, Chung H,Yu LF, Mi ZR, Geng Y, Jing X, Wang SP, Zeng H, Cao GM, Zhao XQ, He J-S* 2014. Non-growing-season soilrespiration is controlled by freezing and thawing processes in the summermonsoon-dominated Tibetan alpine grassland. Global Biogeochemical Cycles28: 1081-1095.

Yang XX, Yang Y, Ji CJ,Feng T, Shi Y, Lin L, Ma JJ, He J-S*2014. Large-scale patterns of stomatal traits in Tibetan and Mongoliangrassland species. Basic and Applied Ecology 15: 122-132.

Shi Y, Wang YH, Ma YL, MaWH, Liang CZ, Flynn DFB, Schmid B, Fang JY, He J-S* 2014. Field-based observations of regional-scale, temporalvariation in net primary production in Tibetan alpine grasslands. Biogeosciences11: 2003-2016.

Baumann F*, Schmidt K,Dörfer C, He J-S, Scholten T, Kühn P2014. Pedogenesis, permafrost, substrate and topography: Plot and landscapescale interrelations of weathering processes on the central-eastern TibetanPlateau. Geoderma 226-227: 300-316.

Geng Y, Wang L, Jin DM, LiuHY, He J-S* 2014. Alpine climatealters the relationships between leaf and root morphological traits but notchemical traits. Oecologia 175: 445-455.

Jing X, Wang YH, Chung H,Mi ZR, Wang SP, Zeng H, He J-S*2014. No temperature acclimation of soil extracellular enzymes to experimentalwarming in an alpine grassland ecosystem on the Tibetan Plateau. Biogeochemistry117: 39-54.

Chen LT, Niu KC, Wu Y, GengY, Mi ZR, Flynn DFB, He J-S* 2013.UV radiation is the primary factor driving the variation in leaf phenolicsacross Chinese grasslands. Ecology and Evolution 3: 4696-4710.

Jin DM, Ma JJ, Ma WH, LiangCZ, Shi Y andHe J-S* 2013. Legumesin Chinese natural grasslands: Species, biomass, and distribution. Rangeland Ecology & Management 66: 648-656.

Du EZ, Zhou Z, Li P, Hu XY,Ma YC, Wang W, Zheng CY, Zhu JX, He J-S,Fang JY* 2013. NEECF: a project of nutrient enrichment experiments in China'sforests. Journal of Plant Ecology 6: 428-435.

HeJ-S*,Muraoka H, Son Y, Fang JY 2013. Carbon patterns and processes in East Asianecosystems: multi-scale approaches (Editorial). Journal of Plant Ecology6: 323-324.

Ma YL, Geng Y, Huang YY,Shi Y, Niklaus P, Schmid B, He J-S*2013. Effect of clear-cutting silviculture on soil respiration in a subtropicalforest of China. Journal of Plant Ecology 6: 335-348.

Yu LF, Wang H, Wang GS,Song WM, Huang Y, Li S-G, Liang NS, Tang YH, He J-S* 2013. A comparison of methane emission measurements usingeddy covariance and manual and automated chamber-based techniques in TibetanPlateau alpine wetland. Environmental Pollution 181: 81-90.

Liu C, Wang XP, Wu X, DaiS, He J-S, Yin WL* 2013. Relativeeffects of phylogeny, biological characters and environments on leaf traits inshrub biomes across central Inner Mongolia, China. Journal of Plant Ecology 6: 220-231.

Jin ZN*, Zhuang QL, He J-S, Luo TX, Shi Y 2013. Phenologyshift from 1989 to 2008 on the Tibetan Plateau: an analysis with aprocess-based soil physical model and remote sensing data. Climatic Change 119: 435-449.

Shi Y, Ma YL, Ma WH, LiangCZ, Zhao XQ, Fang JY, He J-S* 2013.Large scale patterns of forage yield and quality across Chinese grasslands. Chinese Science Bulletin 58: 1187-1199.

Dorfer C*,Kuhn P,Baumann F,He J-S,Scholten T 2013. Soil organiccarbon pools and stocks in permafrost-affected soils on the Tibetan Plateau. PLoS ONE 8: e57024.

Huang N*,He J-S, Niu Z 2013. Estimating thespatial pattern of soil respiration in Tibetan alpine grasslands using LandsatTM images and MODIS data. Ecological Indicators 26: 117-125.

HeJ-S 2012.Carbon cycling of Chinese forests: From carbon storage, dynamics to models. Science China Life Science 55: 188-190.

Geng Y, Wang ZH, Liang CZ,Fang JY, Frank B, Kühn P, Scholten T, HeJ-S* 2012. Effect of geographical range size on plant functional traits andthe relationships between plant, soil and climate in Chinese grasslands. Global Ecology and Biogeography 21: 416–427.

Shi Y, Baumann F, Ma YL,Song C, Kuehn P, Scholten T, He J-S*.2012. Organic and inorganic carbon in the topsoil of the Mongolian and Tibetangrasslands: pattern, control and implications. Biogeosciences 9:2287–2299.

Geng Y,Wang YH,Yang K,WangSP,Zeng H,Baumann F, Kuehn P, Scholten T, HeJ-S* 2012. Soil Respiration in Tibetan Alpine Grasslands: BelowgroundBiomass and Soil Moisture, but Not Soil Temperature, Best Explain theLarge-Scale Patterns. PLoS ONE 7: e34968.

Ma JJ, Ji CJ, Han M, ZhangTF, Yan XD, Hu D, Zeng H, He J-S*2012. Comparative analyses of leaf anatomical characteristics of dicotyledonousspecies in Tibetan and Inner Mongolian grasslands. Science China Life Sciences 42: 158-172.

Tao S*, Wang WT, Liu WX,Zuo Q, Wang XL, Wang R, Wang B, Shen GF, Yang YH, He J-S 2011. Polycyclic aromatic hydrocarbons and organochlorinepesticides in surface soils from the Qinghai-Tibetan plateau. Journal of Environmental Monitoring 13: 175–181.

Chu ZY, Lu YJ, Chang J*,Wang M, Jiang H, He J-S, Peng CH*,Ge Y 2011. Leaf respiration/photosynthesis relationship and variation: aninvestigation of 39 woody and herbaceous species in east subtropical China. Trees-Structureand Function 25: 301-310.

Ma WH, He J-S*, Yang YH, Wang XP, Liang CZ, Anwar M, Zeng H, Fang JY,Schmid B 2010. Environmental factors co-vary with plant diversity-productivityrelationships among Chinese grassland sites. Global Ecology and Biogeography 19: 233–243.

HeJ-S*, WangX, Schmid B, Flynn DFB, Li XF, Reich PB, Fang JY 2010. Taxonomic identity,phylogeny, climate and soil fertility as drivers of leaf traits across Chinesegrassland biomes. Journal of Plant Research 123: 551-561.

Ma WH, Liu ZL, Wang ZH,Wang W, Liang CZ, Tang YH,He J-S,Fang JY* 2010. Climate change alters interannual variation of grasslandaboveground productivity: evidence from a 22-year measurement series in theInner Mongolian grassland. Journal of Plant Research 123:509-517.

Baumann F, He J-S,Schmidt K, Kühn P, Scholten T. 2009. Pedogenesis, permafrost, and soil moistureas controlling factors for soil nitrogen and carbon contents across the TibetanPlateau. Global Change Biology 15: 3001–3017

Yang YH, Fang JY, Smith P,Tang YH, Chen AP, Ji CJ, Hu HF, Rao S, Tan K, He J-S. 2009. Changes intopsoil carbon stock in the Tibetan grasslands between the 1980s and 2004. Global Change Biology 15: 2723–2729

He J-S, Wang XP, Flynn DF, WangL, Schmid B, Fang JY. 2009. Taxonomic, phylogenetic and environmental tradeoffsbetween leaf productivity and persistence.Ecology 90: 2779-2791

He J-S, Wang L, Flynn DFB, WangX, Ma W, Fang J. 2008. Leaf nitrogen: phosphorus stoichiometry across Chinesegrassland biomes. Oecologia155, 301-310

He J-S, Fang JY, Wang ZH, Guo DL,Flynn DFB, Geng Z. 2006. Stoichiometry and large-scale patterns of leaf carbonand nitrogen in the grassland biomes of China. Oecologia, 149:115-122

He J-S, Wang ZH, Wang XP, SchmidB, Zuo W, Zhou M, Zheng CY, Wang MF, Fang JY, 2006. A test of the generality ofleaf trait relationships on the Tibetan Plateau. New Phytologist, 170: 835-848

Balvanera P, Pfisterer AB,Buchmann N, He J-S, Nakashizuka T, Raffaelli D, Schmid B. 2006.Quantifying the evidence for biodiversity effects on ecosystem functioning andservices. Ecology Letters, 99:1146–1156

He J-S, Flynn DFB, Wolfe-BellinK, Fang J, Bazzaz FA. 2005. CO2 and nitrogen, but not populationdensity, alter the size and C/N ratio ofPhytolacca americana seeds. Functional Ecology, 19: 437-444

He J-S, Wolfe-Bellin KS, SchmidB, Bazzaz FA. 2005. Density may alter diversity-productivity relationships inexperimental plant communities. Basicand Applied Ecology, 6: 505-517

He J-S, Wolfe-Bellin KS, BazzazFA. 2005. Leaf-level physiology, biomass, and reproduction of Phytolaccaamericana under conditions of elevated CO2 and alteredtemperature regimes. International Journal of Plant Sciences, 166: 615-622

He J-S, Bazzaz FA. 2003.Density-dependent responses of reproductive allocation to elevated atmosphericCO2 in Phytolacca americana. New Phytologist, 157: 229-239

He J-S, Bazzaz FA, Schmid B.2002. Interactive effects of diversity, nutrients and elevated CO2on experimental plant communities. Oikos,97: 337-348