Evaluating the Tree Population Density and Its Impacts in CLM-DGVM 被引量：1

Evaluating the Tree Population Density and Its Impacts in CLM-DGVM

下载PDF

导出

摘要 Vegetation population dynamics play an essential role in shaping the structure and function of terrestrial ecosystems. However, large uncertainties remain in the parameterizations of population dynamics in current Dynamic Global Vegetation Models （DGVMs）. In this study, the global distribution and probability density functions of tree population densities in the revised Community Land Model-Dynamic Global Vegetation Model （CLM-DGVM） were evaluated, and the impacts of population densities on ecosystem characteristics were investigated. The results showed that the model predicted unrealistically high population density with small individual size of tree PFTs （Plant Punetional Types） in boreal forests, as well as peripheral areas of tropical and temperate forests. Such biases then led to the underestimation of forest carbon storage and incorrect carbon allocation among plant leaves, stems and root pools, and hence predicted shorter time scales for the building/recovering of mature forests. These results imply that further improvements in the parameterizations of population dynamics in the model are needed in order for the model to correctly represent the response of ecosystems to climate change. Vegetation population dynamics play an essential role in shaping the structure and function of terrestrial ecosystems. However, large uncertainties remain in the parameterizations of population dynamics in current Dynamic Global Vegetation Models （DGVMs）. In this study, the global distribution and probability density functions of tree population densities in the revised Community Land Model-Dynamic Global Vegetation Model （CLM-DGVM） were evaluated, and the impacts of population densities on ecosystem characteristics were investigated. The results showed that the model predicted unrealistically high population density with small individual size of tree PFTs （Plant Punetional Types） in boreal forests, as well as peripheral areas of tropical and temperate forests. Such biases then led to the underestimation of forest carbon storage and incorrect carbon allocation among plant leaves, stems and root pools, and hence predicted shorter time scales for the building/recovering of mature forests. These results imply that further improvements in the parameterizations of population dynamics in the model are needed in order for the model to correctly represent the response of ecosystems to climate change.

作者宋翔曾晓东朱家文

机构地区 International Center for Climate and Environment Sciences University of Chinese Academy of Sciences

出处《Advances in Atmospheric Sciences》 SCIE CAS CSCD 2013年第1期116-124,共9页 大气科学进展（英文版）

基金 supported by the Chinese Academy of Sciences (Strategic Priority Re-search Program Grant No. XDA05110103) the StateKey Project for Basic Research Program of China (alsocalled 973 Program,Grant No. 2010CB951801)

关键词 Dynamic Global Vegetation Model population dynamics plant functional type forest carbon storage individual carbon allocation carbon accumulation timeseale Dynamic Global Vegetation Model, population dynamics, plant functional type, forest carbon storage, individual carbon allocation, carbon accumulation timeseale

分类号 X820.3 [环境科学与工程—环境工程]

引文网络
相关文献

参考文献28

1Arora, V. K., and G. J. Boer, 2005: A parameterization of leaf phenology for the terrestrial ecosystem compo- nent of climate models. Global Change Biology, 11, 39-59. 被引量：1
2Bonan, G. B., and S. Levis, 2006: Evaluating aspects of the Community Land and Atmosphere Models (CLM3 and CAM3) using a dynamic global vegeta- tion model. J. Climate, 19, 2290 2301. 被引量：1
3Bugmanm H. K. M., 1996: A simplified forest model to study species composition along climate gradients. Ecology, 77(7), 2055-2074. 被引量：1
4Bugmann,H. K.M., 2001: A review of forest gap models. Climatic Change, 51, 259 305. 被引量：1
5Cheng, G. W., and G. X. Wang, 2010: Gongga Moun- tain station in Sichuan. Forest Ecosystem, Vol. 3, Sta- tion Observation and Research Database of Chinese Ecosystem, China Agricultural Press, Beijing, 150pp. (in Chinese). 被引量：1
6Cox, P. M., 2001: Description of the TRIFFID Dynamic Global Vegetation Model. Hadley Centre Tech. Note 24, Hadley Centre, Bracknell, U.K., 16pp. 被引量：1
7Daly, C., D. Bachelet, J. M. Lenihan, R. P. Neilson, W. Parton, and D. Ojima, 2000: Dynamic simulation of tree-grass interactions for global change studies. Ecological Applications, 10(2), 449-469. 被引量：1
8Deng, X. B., and J. W. Tang, 2010: Xishuangbanna sta- tion in Yunnan. Forest Ecosystem, Vol. 3, Station Ob- servation and Research Database of Chinese Ecosys- tem, China Agricultural Press, Beijing, 380pp. (in Chinese). 被引量：1
9Foley, J. A., S. Levis, I. C. Prentice, D. Pollard, and S. L. Thompson, 1998: Coupling dynamic models of climate and vegetation. Global Change Biology, 4, 561-579. 被引量：1
10Friedlingstein, P., G. Joel, C. B. Field, and I. Y. Fung, 1999: Toward an allocation scheme for global terres- trial carbon models. Global Change Biology, 5, 755- 770. 被引量：1

同被引文献24

1胡远满,徐崇刚,常禹,李秀珍,布仁仓,贺红士,冷文芳.空间直观景观模型LANDIS在大兴安岭呼中林区的应用[J].生态学报,2004,24(9):1846-1856. 被引量：58
2刘华,雷瑞德.我国森林生态系统碳储量和碳平衡的研究方法及进展[J].西北植物学报,2005,25(4):835-843. 被引量：66
3赵东升,李双成,吴绍洪.青藏高原的气候植被模型研究进展[J].地理科学进展,2006,25(4):68-78. 被引量：18
4傅伯杰,赵文武,陈利顶.地理—生态过程研究的进展与展望[J].地理学报,2006,61(11):1123-1131. 被引量：95
5孙艳玲,延晓冬,谢德体,魏朝富.应用动态植被模型LPJ模拟中国植被变化研究[J].西南大学学报（自然科学版）,2007,29(11):86-92. 被引量：16
6苑全治,吴绍洪,赵东升,戴尔阜,陈力,张磊.1961–2005年中国陆地生态系统净初级生产力模拟（英文）[J].Journal of Geographical Sciences.2014(01) 被引量：1
7R. Pavlick,D. T. Drewry,K. Bohn,B. Reu,A. Kleidon.The Jena Diversity-Dynamic Global Vegetation Model (JeDi-DGVM): a diverse approach to representing terrestrial biogeography and biogeochemistry based on plant functional trade-offs[J].Biogeosciences.2013(6) 被引量：1
8Sarah L. Karam,Peter J. Weisberg,Robert M. Scheller,Dale W. Johnson,W. Wally Miller.Development and evaluation of a nutrient cycling extension for the LANDIS-II landscape simulation model[J].Ecological Modelling.2013 被引量：1
9Tang G.,Bartlein P. J.Modifying a dynamic global vegetation model for simulating large spatial scale land surface water balances[J].Hydrology and Earth System Sciences.2012(160) 被引量：1
10Livia Rasche,Lorenz Fahse,Andreas Zingg,Harald Bugmann.Enhancing gap model accuracy by modeling dynamic height growth and dynamic maximum tree height[J].Ecological Modelling.2012 被引量：1

引证文献1

1高西宁,赵亮,尹云鹤.气候变化背景下森林动态模拟研究综述[J].地理科学进展,2014,33(10):1364-1374. 被引量：3

二级引证文献3

1张旭峰,吴水荣,Manfred Lexer,陈绍志,余洋婷.森林生态系统混合斑块模型模拟机理、应用及启示[J].世界林业研究,2020,33(1):1-7.
2罗旭,王聿丽,张金荃.气候变化和林火干扰对大兴安岭林区地上生物量影响的动态模拟[J].应用生态学报,2018,29(3):713-724. 被引量：7
3陈宝,刘志华,房磊.基于多端元光谱混合分析方法的大兴安岭火后植被盖度恢复研究[J].生态学报,2019,39(22):8630-8638. 被引量：2

1王旭峰,马明国,姚辉.动态全球植被模型的研究进展[J].遥感技术与应用,2009,24(2):246-251. 被引量：11
2SUN Guo-Dong.Sensitivity of the Terrestrial Ecosystem to Precipitation and Temperature Variability over China[J].Atmospheric and Oceanic Science Letters,2014,7(5):382-387.
3SUN Guodong,MU Mu.Using the Lund-Potsdam-Jena Model to Understand the Different Responses of Three Woody Plants to Land Use in China[J].Advances in Atmospheric Sciences,2013,30(2):515-524. 被引量：1
4安晓华.珊瑚礁及其生态系统的特征[J].海洋信息,2003(3):19-21. 被引量：1
5耦合动态全球植被模型的古生态系统重建[J].中国科技成果,2016,0(21):34-35.
6毛嘉富,王斌,戴永久,MORALES Pablo.一个动态植被模型在欧洲森林碳水循环模拟中的适应性评估研究[J].大气科学,2008,32(6):1379-1391. 被引量：4
7马杰(翻译).“该不该搁下重重的壳”[J].科学世界,2007(8):76-77.
8ZHU Jia-Wen,ZENG Xiao-Dong.Influences of the interannual variability of vegetation LAI on surface temperature[J].Atmospheric and Oceanic Science Letters,2016,9(4):292-297.
9董海.中国科学家发现南极百年变暖致磷虾种群下降[J].现代渔业信息,2011,26(12):43-43.
10李芳,曾晓东,宋翔,田东晓,邵璞,张东凌.Impact of Spin-up Forcing on Vegetation States Simulated by a Dynamic Global Vegetation Model Coupled with a Land Surface Model[J].Advances in Atmospheric Sciences,2011,28(4):775-788. 被引量：4

Advances in Atmospheric Sciences

2013年第1期

浏览历史

内容加载中请稍等...

Evaluating the Tree Population Density and Its Impacts in CLM-DGVM 被引量：1

参考文献28

同被引文献24

引证文献1

二级引证文献3

相关作者

相关机构

相关主题

浏览历史