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贺金生

职称:教授

研究方向:生态系统生态学,全球变化、生物多样性与生态系统功能、化学计量生态学

通讯地址:

Tel:010-62754404
Email:jshe@pku.edu.cn

个人简历 人才培养 科学研究 教研成果

个人简历

贺金生,男,博士,1965年出生,银河集团9873.cσm教授;兰州大学草种创新与草地农业生态系统全国重点实验室主任。国家自然科学基金委杰出青年基金获得者、科技部“973 计划”(2014-2018)、重点研发计划(2019-2022)项目首席科学家,

主要从事草地生态系统与全球变化、草地生态系统碳循环、化学计量生态学研究。已出版论著章节9篇,发表期刊论文250余篇,其中SCI论文170余篇。论文被引用约18466次(Google Scholar),其中SCI引用约15749余次。担任国务院学位委员会草学学科评议组召集人、第八届教育部科技委环境学部委员、中国草学会副理事长、中国生态学学会理事、北京生态学学会副理事长、中国科学院森林生态与管理重点实验室学术委员会委员、北京师范大学/复旦大学生物多样性与生态工程教育部重点实验室学术委员会委员;《应用生态学报》《生物多样性》、《植物生态学报》等杂志编委,《Journal of Plant Ecology》(5年IF=2.674)杂志编委、Faculty Opinion (原 F1000) Faculty member。

2003年获教育部高校自然科学奖一等奖(第3完成人),2004年获国家自然科学奖二等奖(第5完成人);2022年获基金委“高寒草地生态系统多功能性形成及全球变化下的维持机制”基金重点项目、“不同管理措施下草原优势植物功能性状与群落生产力形成机制”基金重大项目课题,2017年获基金委“高寒草地地上/地下生物多样性和生态系统多功能性对气候变化的响应机制”基金重点项目,2010年获基金委“植物功能属性与化学计量生态学”杰出青年科学基金项目;2020年获科技部“青藏高原退化草地恢复的主要物源制约因子及其应用技术研发”国家重点研发计划项目,2014年获科技部“土壤系统碳动态、机制及其对全球变化的响应”国家重大科学计划“气候变化专项”,2007年获科技部“藏北高寒草甸区生态稳定性维持技术研究与示范”国家科技支撑计划;2011年获中国科学院“青藏高原草地生态系统固碳现状、速率、机制和潜力”战略性先导科技专项子课题。


地址:银河集团9873.cσm

Homepage: http:

Google Scholar Citations: 18466

教育经历

1984.9-1988.7,兰州大学生物系, 理学学士,植物学专业

1988.9-1991.6,中国科学院植物研究所, 理学硕士,植物学专业;导师:陈伟烈

1995.9-1998.8,中国科学院植物研究所, 理学博士,生态学专业;导师:陈灵芝

工作经历

2018.1-今,兰州大学草种创新与草地农业生态系统全国重点实验室主任

2017.7-今,银河集团9873.cσm新体制长聘教授(博雅特聘教授)

2010.9-2014.10,中国科学院高原生物适应与进化重点实验室副主任

2009.3-2012.5,中国科学院西北高原生物研究所“百人计划”研究员

2008.8-今,银河集团9873.cσm生态学系教授

2007.1-2016.5,银河集团9873.cσm生态学系副主任

2002.8-2008.7,银河集团9873.cσm生态学系,副教授

1999.7-2002.8,哈佛大学,博士后

1991.6-1999.6,中国科学院植物研究所, 实习研究员, 助理研究员, 副研究员

杂志任职

2021-今,《陆地生态系统与保护学报》编委

2021-今,《应用生态学报》编委 

2019-今,《Journal of Plant Ecology》Editor (5年IF=2.674)

2009-今,《生物多样性》编委

2008-2019,《Journal of Plant Ecology》Associate Editor

2004-今,《植物生态学报》编委

学术任职

2021-今,中国草学会,副理事长

2020-今,第八届教育部科技委环境学部,委员

2020-今,国务院学位委员会草学学科评议组,召集人

2018-今,中国生态学学会,理事

2018-今,兰州大学草种创新与草地农业生态系统全国重点实验室,主任

2017-今,北京生态学学会,副理事长

2017-2020,重庆大学、西南大学三峡库区生态环境教育部重点实验室学术委员会,委员

2013-今,兰州大学草种创新与草地农业生态系统全国重点实验室学术委员会,委员

2011-今,北京师范大学/复旦大学生物多样性与生态工程教育部重点实验室学术委员会,委员

2011-2020,中国科学院植物研究所植被与环境变化国家重点实验室学术委员会,委员

2011-2017,银河集团9873.cσm地表过程分析与模拟教育部重点实验室,副主任

荣誉与奖励

2016年,西藏自治区科学技术奖,西藏自治区科学技术厅,第10完成人

2015年,银河集团9873.cσm“宝洁”奖

2010年,国家自然科学基金委“杰出青年基金项目”

2006年,银河集团9873.cσm“宝洁”奖

2004年,国家自然科学奖二等奖(项目名称:中国陆地生态系统生产力和碳循环的研究),国务院,第5完成人

2003年,教育部高校自然科学奖一等奖(项目名称:中国陆地生态系统碳循环与植被生产力的研究),教育部,第3完成人

开设课程

主讲本科生必修课《普通生态学(I)》(春季学期)

本科生野外实习课《生态学控制实验野外实习》(暑期)

学生培养

博士生招生方向:植物生态学、全球变化生态学

硕士生招生方向:植物生态学、全球变化生态学


主要研究方向

以草地生态系统为核心,结合生态学多种方法、手段,

研究:

1. 生态系统多功能性的形成及维持机制; 

2. 草原生产力的形成和维持机制;

3. 草地生态系统对全球变化的响应;

4.退化草地的恢复


论著发表情况

章节

1. Jungkunst H.F., Horvath T, Erasmi S, Krüger J.P., Meurer Ka, Schützenmeister K, Guillaume T, Scholten T, Baumann F, Schleuss P, He J-S, Kühn P, Henkner J, Boy J, Kätterer T, Schneider J. 2018. Regionally Diverse Land-Use Driven Feedbacks from Soils to the Climate System. In: Lal R., Stewart B.A. (eds) Soil and Climate. CRC Press, Boca Raton, USA, 61-130.

2. 贺金生. 2017. 草地生态系统生态学. 见于振良主编. 生态学的现状与发展趋势. 354-376. 北京: 高等教育出版社.

3. Pfisterer AB, Balvanera P, Buchmann N, He J-S, Nakashizuka T, Raffaelli D, Schmid B. 2005. The role of biodiversity for ecosystem services: current knowledge. White Paper written for the Swiss Federal Office of the Environment and the Scientific Committee on Problems of the Environment (SCOPE). Swiss Biodiversity Forum, Bern.

4. 刘鸿雁, 贺金生, 方精云. 2004. 全球生态学. 见李文华, 赵景柱主编. 生态学研究回顾

与展望, 402-428. 北京: 气象出版社.

5. 贺金生, 纪力强. 2000. 生物多样性的编目和监测. 见陈灵芝, 马克平主编. 生物多样性科学的理论与实践, 218-248. 上海: 上海科学技术出版社.

6. 贺金生, 马克平. 1996. 物种多样性. 见蒋志刚, 马克平, 韩兴国主编. 保护生物学, 20-33. 杭州: 浙江科学技术出版社.

7. 贺金生, 陈伟烈. 1995. 中国亚热带地区的退化生态系统: 类型、分布、结构特征及恢复途径. 见陈灵芝, 陈伟烈主编, 中国退化生态系统研究, 61-93. 北京: 中国科学技术出版社.

8. 陈伟烈, 贺金生, 谢宗强, 黄汉东, 林成来, 周高尚. 1994. 植被. 见李振宇主编. 龙栖山

植物, 79-127. 北京: 中国科学技术出版社.

9. 陈伟烈, 梁松筠, 谢宗强, 贺金生, 戴伦凯, 金义兴, 江明喜, 张全发, 杨启修, 邱发英, 胡孝綋. 1994. 三峡工程对库区陆生植物和植被的影响. 见姜恕, 陈昌笃主编. 植被生态学研究-纪念著名生态学家侯学煜教授, 174-181. 北京: 科学出版社.

英文期刊论文 (*corresponding author; #co-first author)

1.Qi Q, Zhao JS, Tian RM, Zeng YF, Xie CY, Gao Q, Dai TJ, Wang H, He J-S, Konstantinidis KT, Yang YF, Zhou JZ, Guo X*. 2022. Microbially enhanced methane uptake under warming enlarges ecosystem carbon sink in a Tibetan alpine grassland. Global Change Biology. DOI:10.1111/gcb.16444

2.Gu HJ, Wang H*, Liu M, Shangguan ZJ, Shi HJ, Xu W, Ren F, Zhu JX, He J-S. 2022. Leaf N:P stoichiometry overrides the effect of individual nutrient content on insect herbivore population dynamics in a Tibetan alpine grassland. Agriculture Ecosystems & Environment. 336:108032. DOI: 10.1016/j.agee.2022.108032

3.Yan YJ, Wang JS, Tian DS, Luo YQ, Xue X, Peng F, He J-S, Liu LL, Jiang LF, Wang X, Wang YH, Song L, Niu SL. 2022. Sustained increases in soil respiration accompany increased carbon input under long-term warming across global grasslands. Geoderma. 428(6237):116157. DOI:10.1016/j.geoderma.2022.116157

4.Wang LL, Ren F, Zhang C, Huang XJ, Zhang ZH, He J-S, Yang YP, Duan YW. 2022. The effects of changes in flowering plant composition caused by nitrogen and phosphorus enrichment on plant–pollinator interactions in a Tibetan alpine grassland. Frontiers in Plant Science. 13: 964109. DOI:10.3389/fpls.2022.964109

5.Isbell F*, Balvanera P, Mori AS, He J-S, Bullock JM, Regmi GR, Seabloom EW, Ferrier S, Sala OE, Guerrero-Ramirez NR, Tavella J, Larkin DJ, Schmid B, Outhwaite CL, Pramual P, Borer ET, Loreau M, Omotoriogun TC, Obura DO, Anderson M, Portales-Reyes C, Kirkman K, Vergara PM, Clark AT, Komatsu KJ, Petchey OL, Weiskopf SR, Williams LJ, Collins SL, Eisenhauer N, Trisos CH, Renard D, Wright AJ, Tripathi P, Cowles J, Byrnes JEK, Reich PB, Purvis A, Sharip Z, O'Connor MI, Kazanski CE, Haddad NM, Soto EH, Dee LE, Diaz S, Zirbel CR, Avolio ML, Wang SP, Ma ZY, Liang JJ, Farah HC, Johnson JA, Miller BW, Hautier Y, Smith MD, Knops JMH, Myers BJE, Harmackova ZV, Cortes J, Harfoot MBJ, Gonzalez A, Newbold T, Oehri J, Mazon M, Dobbs C, Palmer MS. 2022. Expert perspectives on global biodiversity loss and its drivers and impacts on people. Frontiers in Ecology and the Environment. DOI: 10.1002/fee.2536

6.Cao ZN, Kuhn P, He J-S, Bauhus J, Guan ZH, Scholten T*. 2022. Calibration of Near-Infrared Spectra for Phosphorus Fractions in Grassland Soils on the Tibetan Plateau. Agronomy. 12(4):783 DOI:10.3390/agronomy12040783

7.Jing X*, Prager CM , Chen LT, Chu HY, Gotelli NJ, He J-S, Shi Y, Yang T, Zhu B, Classen AT, Sanders NJ. 2022. The influence of aboveground and belowground species composition on spatial turnover in nutrient pools in alpine grasslands. Global Ecology and Biogeography. 31(3):486-500 DOI: 10.1111/geb.13442

8.Wang H*, Liu HY, Huang N, Bi J, Ma XL, Ma ZY, Shangguan ZJ, Zhao HF, Feng QS, Liang TG, Cao GM, Schmid B, He J-S. 2021. Satellite-derived NDVI underestimates the advancement of alpine vegetation growth over the past three decades. Ecology. 102:e03518. DOI:10.1002/ecy.3518

9.Zhang ZH*, Wang GS, Wang H, Qi Q, Yang YF, He J-S*. 2021. Warming and drought increase but wetness reduces the net sink of CH4 in alpine meadow on the Tibetan Plateau. Applied Soil Ecology. 167:104061. DOI:10.1016/j.apsoil.2021.104061

10.Li YT, He J-S, Wang H, Zhou JZ, Yang YF*, Chu HY*. 2021. Lowered water table causes species substitution while nitrogen amendment causes species loss in alpine wetland microbial communities. Pedosphere. 31:912-922. DOI:10.1016/S1002-0160(21)60023-1

11.Hu WG, Ran JZ, Dong LW, Du QJ, Ji MF, Yao SR, Sun Y, Gong CM, Hou QQ, Gong HY, Chen RF, Lu JL, Xie SB, Wang ZQ, Huang H, Li XW, Xiong JL, Xia R, Wei MH, Zhao DM, Zhang YH, Li JH, Yang HX, Wang XT, Deng Y, Sun Y, Li HL, Zhang L, Chu QP, Li XW, Aqeel M, Manan A, Akram MA, Liu XH, Li R, Li F, Hou C, Liu JQ, He J-S, An LZ, Bardgett RD*, Schmid B*, Deng JM*. 2021. Aridity-driven shift in biodiversity–soil multifunctionality relationships. Nature Communications. 12:5350. DOI:10.1038/s41467-021-25641-0

12.Jiang SJ, Ling N, Ma ZY, He XJ*, He J-S*. 2021. Short-term warming increases root-associated fungal community dissimilarities among host plant species on the Qinghai-Tibetan Plateau. Plant and Soil. 466:597–611. DOI:10.1007/s11104-021-05073-x

13.Jing X*, Prager CM, Borer ET, Gotelli NJ, Gruner DS, He J-S, Kirkman K, MacDougall AS,   McCulley RL, Prober SM, Seabloom EW, Stevens CJ, Classen AT, Sanders NJ. 2021. Spatial turnover of multiple ecosystem functions is more associated with plant than soil microbial β-diversity. Ecosphere. 12:e03644. DOI:10.1002/ecs2.3644

14.Chen RF, Ran JZ, Hu WG, Dong LW, Ji MF, Jia X, Lu JL, Gong HY, Aqeel M, Yao SR, An LZ, He J-S, Niklas KJ, Deng JM*. 2021. Effects of biotic and abiotic factors on forest biomass fractions. National Science Review. 8:nwab025. DOI:10.1093/nsr/nwab025

15.Chen LT*, Jiang L, Jing X, Wang JL, Shi Y, Chu HY, He J-S. 2021. Above- and belowground biodiversity jointly drive ecosystem stability in natural alpine grasslands on the Tibetan Plateau. Global Ecology and Biogeography. 30:1418-1429. DOI:10.1111/geb.13307

16.Zhang XY, Jia J, Chen LT, Chu HY, He J-S, Zhang YJ, Feng XJ*. 2021. Aridity and NPP constrain contribution of microbial necromass to soil organic carbon in the Qinghai-Tibet alpine grasslands. Soil Biology and Biochemistry. 156:108213. DOI:10.1016/j.soilbio.2021.108213

17.Qi Q, Haowei Y, Zhang ZH, Van Nostrand JD, Wu LW*, Guo X, Feng JJ, Wang MM, Yang SH, Zhao JS, Gao Q, Zhang QT, Zhao MX, Xie CY, Ma ZY, He J-S*, Chu HY, Huang Y, Zhou JZ, Yang YF*. 2021. Microbial functional responses explain alpine soil carbon fluxes under future climate scenarios. mBio. 12:e00761-20. DOI:10.1128/mBio.00761-20

18.Zhu EX, Cao ZJ, Jia J, Liu CZ, Zhang ZH, Wang H, Dai GH, He J-S, Feng XJ*. 2021. Inactive and inefficient:Warming and drought effect on microbial carbon processing in alpine grassland at depth. Global Change Biology. 27:2241-2253. DOI:10.1111/gcb.15541

19.Feng TJ, Zhang LX, Chen Q, Ma ZY, Wang H, Shangguan ZJ, Wang LX, He J-S*. 2021. Dew formation reduction in global warming experiments and the potential consequences. Journal of Hydrology. 593:125819. DOI:10.1016/j.jhydrol.2020.125819

20.Li Y, Yan YJ, Tang ZY*, Wang K, He J-S, Yao YJ*. 2021. Conserving the Chinese caterpillar  fungus under climate change. Biodiversity and Conservation. 30:547-550. DOI:10.1007/s10531-020-02109-z

21.Wang YH, Song C, Liu HY, Wang SP, Zeng H, Luo CY, He J-S*. 2021. Precipitation determines the magnitude and direction of interannual responses of soil respiration to experimental warming. Plant and Soil. 458:75-91. DOI:10.1007/s11104-020-04438-y

22.Liu HY, Lin L, Wang H, Zhang ZH, Shangguan ZJ, Feng XJ, He J-S*. 2021. Simulating warmer and drier climate increases root production but decreases root decomposition in an alpine grassland on the Tibetan plateau. Plant and Soil. 458:59-73. DOI:10.1007/s11104-020-04551-y

23.He J-S*, Dong SK, Shang ZH, Sundqvist MK, Wu GL, Yang YF. 2021. Above-belowground  interactions in alpine ecosystems on the roof of the world. Plant and Soil. 458:1-6. DOI:10.1007/s11104-020-04761-4

24.Yu LF, Wang H, Wang YH, Zhang ZH, Chen LT, Liang N, He J-S*. 2020. Temporal variation in soil respiration and its sensitivity to temperature along a hydrological gradient in an alpine wetland of the Tibetan Plateau. Agricultural and Forest Meteorology. 282–283:107854. DOI:10.1016/j.agrformet.2019.107854

25.Jing X*, Prager CM, Classen AT, Maestre FT, He J-S, Sanders NJ. 2020.Variation in the methods leads to variation in the interpretation of biodiversity-ecosystem multifunctionality relationships. Journal of Plant Ecology. 13:431-441. DOI:10.1093/jpe/rtaa031

26.Luo RY, Kuzyakov Y, Liu DY, Fan JL, Luo JF, Lindsey S, He J-S, Ding WX. 2020. Nutrient addition reduces carbon sequestration in a Tibetan grassland soil: Disentangling microbial and physical controls. Soil Biology and Biochemistry.144:107764. DOI:10.1016/j.soilbio.2020.107764

27.Luo RY, Luo JF, Fan JL, Liu DY, He J-S, Perveen N, Ding WX. 2020. Responses of soil microbial communities and functions associated with organic carbon mineralization to nitrogen addition in a Tibetan grassland. Pedosphere. 30:214-225. DOI:10.1016/s1002-0160(19)60832-5

28.Zhang LH, Yuan FH, Bai JH, Duan HT, Gu XY, Hou LY, Huang YY, Yang MG, He J-S, Zhang ZH, Yu LJ, Song CC, Lipson DA, Zona D, Oechel W, Janssens IA, Xu XF, Coulson T. 2020. Phosphorus alleviation of nitrogen-suppressed methane sink in global grasslands. Ecology Letters. 23:821-830. DOI:10.1111/ele.13480

29.Wang H, Liu HY, Cao GM, Ma ZY, Li YK, Zhang FW, Zhao X, Zhao XQ, Jiang L, Sanders N, Classen A, He J-S*. 2020. Alpine grassland plants grow earlier and faster but biomass remains unchanged over 35 years of climate change. Ecology Letters. 23:701–710. DOI:10.1111/ele.13474

30.Cao JR, Lin L, Pang S, Guo XW, Cao GM, He J-S, Wang QB*. 2020. Early season precipitation accounts for the variability of fine-root traits in a Tibetan alpine grassland. Environmental and Experimental Botany. 172:103991. DOI:10.1016/j.envexpbot.2020.103991

31.Shi Y, Zhang K, Li Q, Liu X, He J-S, Chu HY*. 2020. Interannual climate variability and altered precipitation influence the soil microbial community structure in a Tibetan Plateau grassland. Science of the Total Environment. 714:136794. DOI:10.1016/j.scitotenv.2020.136794

32.Ma T, Dai G, Zhu S, Chen D,  Lü X, Wang X, Zhu J, Zhang Y, He J-S, Bai YF, Han XG, Feng XJ*. 2020. Vertical variations in plant-and microbial-derived carbon components in grassland soils. Plant and Soil. 446:441-455. DOI:10.1007/s11104-019-04371-9

33.Wang C, Ren F, Zhou XH, Ma WH, Liang CZ, Wang JZ, Cheng JW, Zhou HK, He J-S. 2020. Variations in the nitrogen saturation threshold of soil respiration in grassland ecosystems. Biogeochemistry. 148:311–324. DOI:10.1007/s10533-020-00661-y

34.Bond-Lamberty B, Christianson, DS, Malhotra A, Pennington SC, Sihi D, AghaKouchak A, Anjileli H, Arain MA, Armesto J, Ashraf S, Ataka M, Baldocchi D, Black TA, Buchmann N, Carbone MS, Chang SC, Crill P, Curtis PS, Davidson EA, Desai AR, Drake JE, El-Madany TS, Gavazzi M, Gorres CM, Gough CM, Goulden M, Gregg J, del Arroyo OG, He J-S, Hirano T, Hopple A, Hughes H, Jarveoja J, Jassal R, Jian JS, Kan HM, Kaye J, Kominami Y, Liang NS, Lipson D, Macdonald CA, Maseyk K, Mathes K, Mauritz M, Mayes MA, McNulty S, Miao GF, Migliavacca M, Miller S, Miniat CF, Nietz JG, Nilsson MB, Noormets A, Norouzi H, O 'Connell CS, Osborne B, Oyonarte C, Pang Z, Peichl M, Pendall E, Perez-Quezada JF, Phillips CL, Phillips RP, Raich JW, Renchon A, Ruehr NK, Sanchez-Canete EP, Saunders M, Savage KE, Schrumpf M, Scott RL, Seibt U, Silver WL, Sun W, Szutu D, Takagi K, Takagi M, Teramoto M, Tjoelker MG, Trumbore S, Ueyama M, Vargas R, Varner RK, Verfaille J, Vogel C, Wang JS, Winston G, Wood TE, Wu JY, Wutzler T, Zeng J, Zha TS, Zhang Q, Zou JL. 2020. COSORE: A community database for continuous soil respiration and other soil-atmosphere greenhouse gas flux data. Global Change Biology. 26:7268-7283. DOI:10.1111/gcb.15353

35.He NP, Li Y, Liu CC, Xu L, Li MX, Zhang JH, He J-S, Tang ZY, Han XG, Ye Q, Xiao CW, Yu Q, Liu SR, Sun W, Niu SL, Li SG, Sack L, Yu GR. 2020. Plant Trait Networks: Improved Resolution of the Dimensionality of Adaptation. Trends in Ecology & Evolution. 35:908-918. DOI:10.1016/j.tree.2020.06.003

36.Feng TJ, Zhang LX, Chen Q, Ma ZY, Wang H, Shangguan ZJ, Wang LX, He J-S. 2020. Infrared heater warming system markedly reduces dew formation: An overlooked factor in arid ecosystems. BioRxiv. DOI:10.1101/2020.02.15.950584

37.Tian D, Kattge J, Chen YH, Han WX, Luo YK, He J-S, Hu HF, Tang ZY, Ma SH, Yan ZB, Lin QH, Schmid B, Fang JY. 2019. A global database of paired leaf nitrogen and phosphorus concentrations of terrestrial plants. Ecology. 100:e02812. DOI:10.1002/ecy.2812

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122.Geng Y, Wang L, Jin DM, Liu HY, He J-S*. 2014. Alpine climate alters the relationships between leaf and root morphological traits but not chemical traits. Oecologia. 175:445-455. DOI:10.1007/s00442-014-2919-5

123.Baumann F, Schmidt K, Dörfer C, He J-S, Scholten T, Kühn P. 2014. Pedogenesis, permafrost, substrate and topography: Plot and landscape scale interrelations of weathering processes on the central-eastern Tibetan Plateau. Geoderma. 226-227:300-316. DOI:10.1016/j.geoderma.2014.02.019

124.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 Mongolian grassland species. Basic and Applied Ecology. 15:122-132. DOI:10.1016/j.baae.2014.01.003

125.Shi Y, Wang Y, Ma W, Liang C, Flynn DFB, Schmid B, Fang JY, He J-S*. 2014. Field-based observations of regional-scale, temporal variation in net primary production in Tibetan alpine grasslands. Biogeosciences. 11:2003-2016. DOI:10.5194/bg-11-2003-2014

126.Bruelheide H, Nadrowski K, Assmann T, Bauhus J, Both S, Buscot F, Chen XY, Ding BY, Durka W, Erfmeier A, Gutknecht JLM, Guo DL, Guo LD, Härdtle W, He J-S, Klein AM, Kühn P, Liang Y, Liu XJ, Michalski S, Niklaus PA, Pei KQ, Scherer-Lorenzen M, Scholten T, Schuldt A, Seidler G, Trogisch S, von Oheimb G, Welk E, Wirth C, Wubet T, Yang XF, Yu MJ, Zhang SR, Zhou HZ, Fischer M, Ma KP, Schmid B. 2014. Designing forest biodiversity experiments: general considerations illustrated by a new large experiment in subtropical China. Methods in Ecology and Evolution. 5:74-89. DOI:10.1111/2041-210x.12126

127.Jing X, Wang YH, Chung H, Mi ZR, Wang SP, Zeng H, He J-S*. 2014. No temperature acclimation of soil extracellular enzymes to experimental warming in an alpine grassland ecosystem on the Tibetan Plateau. Biogeochemistry. 117:39-54. DOI:10.1007/s10533-013-9844-2

128.Eichenberg D, Trogisch S, Huang YY, He J-S, Bruelheide H. 2014. Shifts in community leaf functional traits relate to litter decomposition litter decomposition along a secondary forest succession series in subtropical China. Journal of Plant Ecology. 8:401-410. DOI:10.1093/jpe/rtu021

129.Chen LT, Niu KC, Wu Y, Geng Y, Mi ZR, Flynn DFB, He J-S*. 2013. UV radiation is the primary factor driving the variation in leaf phenolics across Chinese grasslands. Ecology and Evolution. 3:4696-4710. DOI:10.1002/ece3.862

130.Jin DM, Ma JJ, Ma WH, Liang CZ, Shi Y, He J-S*. 2013. Legumes in Chinese natural grasslands: Species, biomass, and distribution. Rangeland Ecology & Management. 66:648–656. DOI:10.2111/rem-d-12-00159.1

131.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’s forests. Journal of Plant Ecology. 6:428-435. DOI:10.1093/jpe/rtt008

132.He J-S, Muraoka H, Son Y, Fang JY. 2013. Carbon patterns and processes in East Asian ecosystems: multi-scale approaches. Journal of Plant Ecology. 6:323-324. DOI:10.1093/jpe/rtt052

133.Ma YL, Geng Y, Huang YY, Shi Y, Niklaus PA, Schmid B, He J-S*. 2013. Effect of clear-cutting silviculture on soil respiration in a subtropical forest of China. Journal of Plant Ecology. 6:335-348. DOI:10.1093/jpe/rtt038

134.Yu LF, Wang H, Wang GS, Song WM, Huang Y, Li SG, Liang NS, Tang YH, He J-S*. 2013. A comparison of methane emission measurements using eddy covariance and manual and automated chamber-based techniques in Tibetan Plateau alpine wetland. Environmental Pollution. 181:81-90. DOI:10.1016/j.envpol.2013.06.018

135.Wang S, Ni HG, Sun JL, Jing X, He J-S, Hui Z. 2013. Polycyclic aromatic hydrocarbons in soils from the Tibetan Plateau, China: distribution and influence of environmental factors. Environmental Science: Processes & Impacts.15:661-667. DOI:10.1039/c2em30856h

136.Jin ZN*, Zhuang QL, He J-S, Luo TX, Shi Y. 2013. Phenology shift from 1989 to 2008 on the Tibetan Plateau: an analysis with a process-based soil physical model and remote sensing data. Climatic Change. 119:435-449. DOI:10.1007/s10584-013-0722-7

137.Liu C, Wang XP, Wu X, Dai S, He J-S, Yin WL. 2013. Relative effects of phylogeny, biological characters and environments on leaf traits in shrub biomes across central Inner Mongolia, China. Journal of Plant Ecology. 6:220–231. DOI:10.1093/jpe/rts028

138.Shi Y, Ma YL, Ma WH, Liang CZ, 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. DOI:10.1007/s11434-012-5493-4

139.Dörfer C, Kühn P, Baumann F, He J-S, Scholten T. 2013. Soil organic carbon pools and stocks in permafrost-affected soils on the Tibetan Plateau. Plos One. 8:e57024. DOI:10.1371/journal.pone.0057024

140.Huang N, He J-S, Niu Z. 2013. Estimating the spatial pattern of soil respiration in Tibetan alpine grasslands using Landsat TM images and MODIS data. Ecological Indicators. 26:117–125. DOI:10.1016/j.ecolind.2012.10.027

141.Liang NS, Wang Y, Zhang Y, He J-S, Li S, Piao SL, Fang JY, Hirano T, Takagi K, Fletcher CD, Teramoto M, Tan ZH. 2013. An automatedchamber network for evaluation of carbon budget of Asian terrestrial ecosystems. AsiaFlux Newsletter. 35:3–12.

142.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 Tibetan grasslands: pattern, control and implications. Biogeosciences. 9:2287-2299. DOI:10.5194/bg-9-2287-2012

143.Geng Y, Wang YH, Yang K, Wang SP, Zeng H, Baumann F, Kuehn P, Scholten T, He J-S*. 2012. Soil respiration in Tibetan alpine grasslands: Belowground biomass and soil moisture, but not soil temperature, best explain the large-scale patterns. Plos One. 7:e34968. DOI:10.1371/journal.pone.0034968

144.He J-S. 2012. Carbon cycling of Chinese forests: from carbon storage, dynamics to models. Science China Life Sciences. 55:188–190. DOI:10.1007/s11427-012-4285-Z

145.Ma JJ, Ji CJ, Han M, Zhang TF, Yan XD, Hu D, Zeng H, He J-S. 2012. Comparative analyses of leaf anatomical characteristics of dicotyledonous species in Tibetan and Inner Mongolian grasslands. Science China Life Sciences. 55:68-79. DOI:10.1007/s11427-012-4268-0

146.Geng Y, Wang ZH, Liang CZ, Fang JY, Frank B, Kühn P, Scholten T, He J-S*. 2012. Effect of geographical range size on plant functional traits and the relationships between plant, soil and climate in Chinese grasslands. Global Ecology and Biogeography. 21:416–427. DOI:10.1111/j.1466-8238.2011.00692.x

147.Chu ZY, Lu YJ, Chang J, Wang M, Jiang H, He J-S, Peng CH, Ge Y. 2011. Leaf respiration/ photosynthesis relationship and variation: an investigation of 39 woody and herbaceous species in east subtropical China. Trees-Structure and Function. 25:301-310. DOI:10.1007/s00468-010-0506-x

148.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 organochlorine pesticides in surface soils from the Qinghai-Tibetan plateau. Journal of Environmental Monitoring. 13:175–181. DOI:10.1039/c0em00298d

149.Bruelheide H, Böhnke M, Both S, Fang T, Assmann T, Baruffol M, Bauhus J, Buscot F, Chen XY, Ding BY, Durka W, Erfmeier A, Fischer M, Geißler C, Guo DL, Guo LD, Härdtle W, He J-S, Hector A, Kröber W, Kühn P, Lang AC, Nadrowski K, Pei KQ, Scherer-Lorenzen M, Shi XZ, Scholten T, Schuldt A, Trogisch S, von Oheimb G, Welk E, Wirth C, Wu YT, Yang XF, Zeng XQ, Zhang SR, Zhou HZ, Ma KP, Schmid B. 2011. Community assembly during secondary forest succession in a Chinese subtropical forest. Ecological Monographs. 81:25-41. DOI:10.1890/09-2172.1

150.Ma WH, Liu ZL, Wang ZH, Wang W, Liang CZ, Tang YH, He J-S, Fang JY. 2010. Climate change alters interannual variation of grassland aboveground productivity: evidence from a 22-year measurement series in the Inner Mongolian grassland. Journal of Plant Research.123:509-517. DOI:10.1007/s10265-009-0302-0

151.He J-S, Wang X, Schmid B, Flynn DFB, Li XF, Reich PB, Fang JY. 2010. Taxonomic identity, phylogeny, climate and soil fertility as drivers of leaf traits across Chinese grassland biomes. Journal of Plant Research. 123:551-561. DOI:10.1007/s10265-009-0294-9

152.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-productivity relationships among Chinese grassland sites. Global Ecology and Biogeography. 19:233–243. DOI:10.1111/j.1466-8238.2009.00508.x

153.Tang YH, Wan SQ, He J-S, Zhao XQ. 2009. Foreword to the special issue:looking into the impacts of global warming from the roof of the world. Journal of Plant Ecology. 2:169-171. DOI:10.1093/jpe/rtp026

154.Baumann F, He J-S, Schmidt K, Kühn P, Scholten T. 2009. Pedogenesis, permafrost, and soil moisture as controlling factors for soil nitrogen and carbon contents across the Tibetan Plateau. Global Change Biology. 15:3001–3017. DOI:10.1111/j.1365-2486.2009.01953.X

155.Yang YH, Fang JY, Smith P, Tang YH, Chen AP, Ji CJ, Hu HF, Rao S, Tan K, He J-S. 2009. Changes in topsoil carbon stock in the Tibetan grasslands between the 1980s and 2004. Global Change Biology. 15: 2723–2729. DOI:10.1111/j.1365-2486.2009.01924.x

156.He J-S, Wang XP, Flynn DFB, Wang L, Schmid B, Fang JY. 2009. Taxonomic, phylogenetic and environmental tradeoffs between leaf productivity and persistence. Ecology. 90:2779-2791. DOI:10.1890/08-1126.1

157.He J-S, Wang L, Flynn DFB, Wang X, Ma W, Fang JY. 2008. Leaf nitrogen: phosphorus stoichiometry across Chinese grassland biomes. Oecologia. 155:301-310. DOI:10.1007/s00442-007-0912-y

158.Yang YH, Fang JY, Tang YH, Ji CJ, Zheng CY, He J-S, Zhu B. 2008. Storage, patterns and controls of soil organic carbon in the Tibetan grasslands. Global Change Biology. 14:1592-1599. DOI:10.1111/j.1365-2486.2008.01591.x

159.Flynn D, Schmid B, He J-S, Wolfe-Bellin KS, Bazzaz FA. 2008. Hierarchical reliability in experimental plant communities. Journal of Plant Ecology. 1:59-65. DOI:10.1093/jpe/rtm004

160.Ma WH, Yang YH, He J-S, Zeng H, Fang JY. 2008. Above- and belowground biomass in relation to environmental factors in temperate grasslands, Inner Mongolia. Science in China Series C-Life Sciences. 51:263-270. DOI:10.1007/s11427-008-0029-5

161.Wolfe-Bellin KS, He J-S, Bazzaz FA. 2006. Leaf-level physiology, biomass and reproduction of Phytolacca americana under conditions of elevated carbon dioxide and increased nocturnal temperature. International Journal of Plant Sciences. 167:1011-1020. DOI:10.1086/506154

162.Qian H, Wang S, He J-S, Zhang JL, Wang LS, Wang XL, Guo K. 2006. Phytogeographical Analysis of Seed Plant Genera in China. Annals of Botany. 98:1073–1084. DOI:10.1093/aob/mcl192

163.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 and services. Ecology Letters. 99:1146–1156. DOI:10.1111/j.1461-0248.2006.00963.x

164.He J-S, Fang JY, Wang ZH, Flynn DFB, Geng Z. 2006. Stoichiometry and large-scale patterns of leaf carbon and nitrogen in the grassland biomes of China. Oecologia. 149:115-122.DOI: 10.1007/s00442-006-0425-0

165.He J-S, Wang ZH, Wang XP, Schmid B, Zuo W, Zhou M, Zheng CY, Wang MF, Fang JY. 2006. A test of the generality of leaf trait relationships on the Tibetan Plateau. New Phytologist. 170:835-848. DOI:10.1111/j.1469-8137.2006.01704.x

166.Piao SL, Fang JY, He J-S. 2006. Variations in vegetation net primary production in the Qinghai-Xizang Plateau, China, from 1982 to 1999. Climatic Change. 74:253–267. DOI:10.1007/s10584-005-6339-8

167.Fang JY, Piao SL, Zhou L, He J-S, Wei FY, Myneni R, Tucker CJ, Tan K. 2005. Precipitation patterns alter growth of temperate vegetation. Geophysical Research Letters. 32:L21411. DOI:10.1029/2005GL024231.

168.He J-S, Wolfe-Bellin KS, Schmid B, Bazzaz FA. 2005. Density may alter diversity-productivity relationships in experimental plant communities. Basic and Applied Ecology. 6:505-517. DOI:10.1016/j.baae.2005.04.002

169.He J-S, Flynn DFB, Wolfe-Bellin KS, Fang J, Bazzaz FA. 2005. CO2 and nitrogen, but not population density, alter the size and C/N ratio of Phytolacca americana seeds. Functional Ecology. 19:437-444. DOI:10.1111/j.1365-2435.2005.00981.x

170.He J-S, Wolfe-Bellin KS, Bazzaz FA. 2005. Leaf-level physiology, biomass, and reproduction of Phytolacca americana under conditions of elevated CO2 and altered temperature regimes. International Journal of Plant Sciences. 166:615-622. DOI:10.1086/430196

171.He J-S, Zhang QB, Bazzaz FA. 2005. Differential drought responses between saplings and adult trees in four co-occurring species of New England. Trees-Structure and Function. 19:442-450. DOI:10.1007/s00468-004-0403-2

172.He J-S, Wang ZQ, Fang JY. 2004. Issues and prospects of belowground ecology with special reference to global climate change. Chinese Science Bulletin. 49:1891-1899. DOI:10.1360/03wd0558

173.Fang JY, Piao SL, He J-S, Ma WH. 2004. Increasing terrestrial vegetation activity in China, 1982-1999. Science in China Series C Life Sciences. 47:229-240. DOI:10.1360/03yc0068

174.He J-S, Bazzaz FA. 2003. Density-dependent responses of reproductive allocation to elevated atmospheric CO2 in Phytolacca americana. New Phytologist. 157:229-239. DOI:10.1046/j.1469-8137.2003.00660.x

175.He J-S, Bazzaz FA, Schmid B. 2002. Interactive effects of diversity, nutrients and elevated CO2 on experimental plant communities. Oikos. 97:337-348. DOI:10.1034/j.1600-0706.2002.970304.x

中文期刊论文

1. 赵翊含, 侯蒙京, 冯琦胜, 高宏元, 梁天刚*, 贺金生, 钱大文. 2022. 基于Landsat 8和随机森林的青海门源天然草地地上生物量遥感估算. 草业学报. 31(7):1-14.

2. 南志标, 王彦荣, 贺金生, 胡小文, 刘志鹏, 李春杰, 聂斌, 夏超. 2022. 我国草种业的成就、挑战与展望. 草业学报. 31(6):1-10.

3. 顾慧洁, 汪浩*, 上官子健, 石慧瑾, 朱剑霄, 贺金生. 2022. 外源氮添加对高寒草地门源草原毛虫种群密度的影响. 生态学报. 42(5):1958-1967.

4. 高宏元, 侯蒙京, 葛静, 包旭莹, 李元春, 刘洁, 冯琦胜, 梁天刚*, 贺金生, 钱大文. 2021. 基于随机森林的高寒草地地上生物量高光谱估算. 草地学报. 29(08):1757-1768.

5. 王常顺, 吕汪汪, 孙建平, 周阳, 姜丽丽, 李博文, 阿旺, 张苏人, 夏露, 王奇, 斯确多吉, 贺金生, 汪诗平*. 2021. 高寒植物叶片性状对模拟降水变化的响应研究. 生态学报. 41(24)1-13.

6. 井新*, 贺金生. 2021. 生物多样性与生态系统多功能性和多服务性关系的研究: 回顾与展望. 植物生态学报. 45(10).

7. 陈哲, 汪浩*, 王金洲, 石慧瑾, 刘慧颖, 贺金生. 2021. 基于物候相机NDVI估算高寒草地植物地上生物量的季节动态. 植物生态学报. 45(05):487-495. DOI:10.17521/cjpe.2020.0076

8. 冯天骄, 张智起, 张立旭, 徐炜, 贺金生. 2021. 干旱半干旱区生态系统凝结水影响因素及作用的研究进展. 生态学报. 41(2):456-468.

9. 贺金生, 卜海燕, 胡小文, 冯彦皓, 李守丽, 朱剑霄, 刘国华, 王彦荣, 南志标. 2020. 退化高寒草地的近自然恢复:理论基础与技术途径. 科学通. 65(34):3898-3908

10. 贺金生, 刘志鹏, 姚拓, 孙书存, 吕植, 胡小文, 曹广民, 吴新卫, 李黎, 卜海燕, 朱剑霄. 2020. 青藏高原退化草地恢复的主要制约因子及修复技术. 科技导报. 38(17):66-80

11. 蒋胜竞, 冯天骄, 刘国华, 贺金生*. 2020. 草地生态修复技术应用的文献计量分析. 草业科学. 37(4):685-702

12. 关振寰, 刘国华, 贺金生*. 2020. 草地保护技术研究现状及发展趋势的文献分析. 草业科学. 37(4):703-717

13.李熠, 唐志尧, 闫昱晶, 王科, 蔡磊, 贺金生, 古松, 姚一建. 2020. 物种分布模型在大型真菌红色名录评估及保护中的应用:以冬虫夏草为例. 生物多样性. 28(1):99-106

14.张智起, 张立旭, 徐炜, 汪浩, 王金洲, 王娓, 贺金生*. 2019. 气候变暖背景下土壤呼吸研究的几个重要问题. 草业学报. 28 (9):164-173

15.刘安榕, 杨腾, 徐炜, 上官子健, 王金洲, 刘慧颖, 时玉, 褚海燕, 贺金生*. 2018. 青藏高原高寒草地地下生物多样性: 进展、问题与展望. 生物多样性. 26 (9):972–987

16.张则瑾, 郭焱培, 贺金生, 唐志尧. 2018. 中国极小种群野生植物的保护现状评估. 生物多样性. 26 (6):572–577

17.李颖, 林笠, 朱文琰, 张振华, 贺金生. 2017. 青藏高原高寒草地常见植物叶属性对氮、磷添加的响应. 银河集团9873.cσm学报(自然科学版). 53(3):535-544.

18.杨新宇, 林笠, 李颖, 贺金生. 2017. 青藏高原高寒草甸土壤物理性质及碳组分对增温和降水改变的响应. 银河集团9873.cσm学报(自然科学版). 53(4):765-774

19.林笠, 王其兵, 张振华*, 贺金生*. 2017.  温暖化加剧青藏高原高寒草甸土非季节性冻融循环. 银河集团9873.cσm学报. 53(1):171-178

20.林笠, 王其兵*, 贺金生*. 2016.  青藏高原高寒草甸土发生季节性潜育化及其生态学意义. 银河集团9873.cσm学报. 52(6):1161-1166

21.武丹丹, 井新, 林笠, 杨新宇, 张振华, 贺金生*. 2016. 青藏高原高寒草甸土壤无机氮对增温和降水改变的响应. 银河集团9873.cσm学报. 52(5):959-966

22.戴国华, 朱珊珊, 刘宗广, 陈立同, 贺金生, 冯晓娟. 2016. 青藏高原高寒草地土壤中脂肪酸的分布特征.中国科学:地球科学. 46(6):756-766

23.徐炜, 马志远, 井新, 贺金生*. 2016. 生物多样性与生态系统多功能性: 进展和展望. 生物多样性. 24(1):55–71

24.徐炜, 井新, 马志远, 贺金生*. 2016. 生态系统多功能性的测度方法. 生物多样性. 24(1):72–84

25.米兆荣, 陈立同, 张振华, 贺金生*. 2015. 基于年降水、生长季降水和生长季蒸散的高寒草地水分 利用效率. 植物生态学报. 39(7):649–660

26.黄园园, OLBRECHT Luise, 杨晓霞, 贺金生*. 2014. 养分添加对青藏高原高寒草甸丛枝菌根真菌的影响. 银河集团9873.cσm学报 (自然科学版). 50(5):911-918

27.徐敏云, 贺金生. 2014. 草地载畜量研究进展:概念、理论和模型. 草业学报. 23(3):313-324

28.汪浩, 于凌飞, 陈立同, 王超, 贺金生*, 2014. 青藏高原海北高寒湿地土壤呼吸对水位降低和氮添加的响应. 植物生态学报. 38(6):619–625

29.杨晓霞, 任飞, 周华坤, 贺金生*. 2014.青藏高原高寒草甸植物生物量对氮、磷添加的响应. 植物生态学报. 38(2):159-166

30.任飞, 杨晓霞, 周华坤, 姚步青, 王文颖, 温军, 贺金生, 赵新全. 2013. 青藏高原高寒草甸3种植物对模拟增温的生理生化响应. 西北植物学报. 33(11):2257-2264.

31.王广帅, 杨晓霞, 任飞, 张振华, 贺金生*. 2013. 青藏高原高寒草甸非生长季温室气体排放特征及其年度贡献.  生态学杂志. 32(8):1994-2001

32.杨莉, 师生波, 贺金生*. 2013. 青海省玛沁县冬虫夏草适生地植物群落及土壤理化性质分析. 草地学报. 21(03):467-473

33.方精云, 朱江玲, 吉成均, 唐志尧, 贺金生. 2013. 从生态学观点看生态文明建设. 中国科学院院刊 28(2):182-188

34.石岳, 马殷雷, 马文红, 梁存柱, 赵新全, 方精云, 贺金生. 2013. 中国草地的产草量和牧草质量: 格局及其与环境因子之间的关系. 科学通报. 58(3):226-239

35.贺金生. 2012. 中国森林生态系统的碳循环: 从储量、动态到模式. 中国科学.  42(3):252-254

36.马建静, 吉成均, 韩梅, 张婷芳, 闫雪东, 胡东, 曾辉, 贺金生. 2012. 青藏高原高寒草地和内蒙古高原温带草地主要双子叶植物叶片解剖特征的比较研究. 中国科学:生命科学. 42(2):165-179

37.李英年, 赵新全, 张法伟, 杜明远, 汪诗平, 贺金生. 2011. 祁连山冷龙岭南坡移地植物叶片的碳氮特征. 西北植物学报. 31(04):788-794

38.耿燕, 吴漪, 贺金生. 2011. 内蒙古草地叶片磷含量与土壤有效磷的关系. 植物生态学报. 35(1):1-8

39.贺金生, 韩兴国. 2010. 生态化学计量学: 探索从个体到生态系统的统一化理论. 植物生态学报. 34(1):2-6

40.杨阔, 黄建辉, 董丹, 马文红, 贺金生. 2010. 青藏高原草地植物群落冠层叶片氮磷化学计量学分析. 植物生态学报. 34(1):17-22

41.徐冰, 程雨曦, 周文嘉, 甘慧洁, 贺金生*.2010. 内蒙古锡林河流域典型草原植物叶片与细根属性在种间及种内水平上的关联. 植物生态学报. 34(1):29-38

42.周鹏, 耿燕, 马文红, 贺金生*. 2010. 温带草地主要优势植物不同器官间功能性状的关联. 植物生态学报.34(1):7-16

43.方精云, 王襄平, 沈泽昊, 唐志尧, 贺金生, 于丹, 江源, 王志恒, 郑成洋, 朱江玲, 郭兆迪. 2009. 植物群落清查的主要内容、方法和技术规范.  生物多样性.17(6):533-548.

44.魏天凤, 任艳林, 曾辉, 贺金生*. 2009.降水改变对樟子松人工林土壤微生物量碳、微生物商动态变化的影响. 银河集团9873.cσm学报(自然科学版). 45(3):533-540

45.刘畅, 任艳林, 贺金生*. 2009. 草地造林对土壤可溶性有机碳、总有机碳和全氮的影响. 银河集团9873.cσm学报(自然科学版). 45(3):511-518

46.韩文轩, 吴漪, 汤璐瑛, 陈雅涵, 李利平, 贺金生, 方精云. 2009. 北京及周边地区植物叶的碳氮磷元素计量特征. 银河集团9873.cσm学报(自然科学版). 45(5):855-860

47.马文红, 杨元合, 贺金生, 曾辉, 方精云. 2008.  蒙古温带草地生物量及其与环境因子的关系. 中国科学(C辑:生命科学). 38(1):84-92

48.王向雨, 胡东, 贺金生. 2007. 神农架地区米心水青冈林和锐齿槲栎林生物量的研究. 首都师范大学学报(自然科学版). 28(2):62-67

49.韩梅, 吉成均, 左闻韵, 贺金生*. 2006. CO2 浓度和温度升高对11种植物叶片解剖特征的影响. 生态学报. 26(2):326-333

50.左闻韵, 贺金生*, 韩梅, 吉成均, Dan F.B. Flynn, 方精云. 2005. 植物气孔对大气CO2浓度和温度升高的反应——基于在CO2浓度和温度梯度中生长的10种植物的观测. 生态学报. 25(3):565-574

51.朴世龙, 方精云, 贺金生, 肖玉. 2004. 中国草地植被生物量及其空间分布格局. 植物生态学报. 28(4):491-498

52.贺金生, 王政权, 方精云. 2004. 全球变化下的地下生态学: 问题与展望. 科学通报. 49(13):1226-1233

53.李海涛, 贺金生, 倪志诚, 周榜第, 李乾振, 沈文清. 2004. 西藏拉孜县草地植物群落的TWINSPAN 分类及其物种多样性研究. 江西农业大学学报. 26(1):31-36

54.贺金生, 方精云, 马克平, 黄建辉. 2003. 生物多样性与生态系统生产力: 为什么野外观测和受控实验结果不一致? 植物生态学报. 27(6):835-843

55.方精云, 朴世龙, 贺金生, 马文红. 2003. 近20年来中国植被活动在增强. 中国科学 (C辑:生命科学).  33(6):554-565

56.刘峰, 陈伟烈, 贺金生. 2000. 神农架地区锐齿槲栎种群结构与更新的研究. 植物生态学报. 24(4):396-401

57.刘峰, 贺金生, 陈伟烈. 1999. 生物多样性的生态系统功能. 植物学通报. 16(6):671-676

58.贺金生, 刘峰, 陈伟烈, 陈灵芝. 1999. 神农架地区米心水青冈林和锐齿槲栎林群落干扰历史及更新策略. 植物学报. 41(8):887-892

59.李凌浩, 林鹏, 王其兵, 贺金生, 何建源, 刘初钿, 金昌善, 陈仁华. 1998. 武夷山不同林龄甜槠林水文学效应的比较研究.  应用生态学报. 9(1):18-22

60.王其兵, 李凌浩, 刘先华, 贺金生. 1998. 内蒙古锡林河流域草原土壤有机碳及氮素的空间异质性分析. 植物生态学报. 22(5):409-414

61.贺金生, 陈伟烈, 刘峰. 1998. 神农架地区米心水青冈萌枝过程的研究. 植物生态学报. 22(5):385-391

62.贺金生, 陈伟烈, 李凌浩. 1998. 中国中亚热带东部常绿阔叶林主要类型的群落多样性特征. 植物生态学报. 22(4):303-311

63.贺金生, 陈伟烈, 谢宗强, 胡东. 1998. 福建龙栖山自然保护区的常绿阔叶林类型及其群落物种多样性分析. 生态学杂志. 17(3):1-6

64.贺金生, 陈伟烈, 江明喜, 金义兴, 胡东, 路鹏. 1998. 长江三峡地区退化生态系统植物群落物种多样性特征. 生态学报. 18(4):291-299

65.贺金生,陈伟烈,王其兵. 1998. 长江三峡地区优势植物的化学元素含量特征.植物学报. 40(5):453-460

66.王其兵, 贺金生, 陈伟烈. 1997. 长江三峡地区退化生态系统土壤微生物的初步研究. 生物多样性. 5(4):241-245

67.贺金生, 王其兵, 胡东. 1997. 长江三峡地区典型灌丛的生物量及其再生能力. 植物生态学报. 21(6):512-520

68.李凌浩, 林鹏, 王其兵, 贺金生, 何建源, 刘初钿, 金昌善, 陈仁华. 1997. 武夷山甜槠林水文学效应的研究. 植物生态学报. 21(5):393-402

69.贺金生, 陈伟烈. 1997. 陆地植物群落物种多样性的梯度变化特征. 生态学报. 17(1):91-9

70.谢宗强, 陈伟烈, 梁松筠, 贺金生. 1995. 三峡库区的珍稀濒危植物及其保护. 北京林业大学学报. 17(4):82-87

71.林洁, 沈泽昊, 贺金生, 陈伟烈. 1995. 珙桐群落学特征及群落环境分析. 植物学通报. 12(S2):71-78

72.贺金生, 林洁, 陈伟烈. 1995. 我国珍稀特有植物珙桐的现状与保护. 生物多样性. 3(4):213-221

73.江明喜, 金义兴, 贺金生, 陈伟烈, 沈泽昊. 1995. 人为干扰对马尾松次生林植物多样性的影响. 长江流域资源与环境. 4(4):356-361

74.贺金生, 王勋陵, 陈伟烈. 1994. 试用多元分析方法研究植物形态结构与生态环境的关系. 应用生态学报. 5(4):378-384

75.贺金生, 陈伟烈, 王勋陵. 1994. 高山栎叶的形态结构特征及其与生态环境的关系. 植物生态学报. 18(3):219-227

76.王勋陵, 贺金生, 黄韵珠. 1991. 臭氧对蚕豆 (Vicia faba) 光合作用的影响及Mefluidide的防护效应. 生态学报. 11(2):189-190

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12.2020年09月25日,高寒生态年会暨第三届西藏高原生态安全论坛,高寒草地生物多样性的动态变化及近自然恢复

13.2020年08月22日,全国草业科学院所长联盟、国家林业和草原局草地资源保护国家创新联盟2020年会暨草地生态系统保护与草业发展,高寒草地生物多样性、生态系统多服务性及近自然恢复

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15.2020年01月04日,第八届中国草原论坛暨首届CAU草学前沿论坛,基于长期监测的草地生物多样性与生态系统功能研究

16.2019年11月20日,蒙古高原草原生态系统管理暨中科院内蒙古草原生态系统定位研究站建站40周年学术研讨会,高寒草地的生物多样性与生态系统功能基千长期监测的研究

17.2019年11月17日-19日,生物多样性前沿论坛暨《生物多样性》编委会会议,气候变化下高寒草地的生物多样性与生态系统功能

18.2019年10月31日,内蒙古自治区草原学会年会,全球变化下的草地农业研究

19.2019年09月24-25日,沈阳农业大学生物科学技术学院建院20周年暨生命科学创新与农业发展高峰论坛,全球变化下的草地生态学与草地农业研究

20.2019年08月04-07日,“西部地区草地农业生态/水土保持与生态修复学术研讨会”,草地农业生态系统研究进展

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