陆地生态系统环境控制实验的研究方法及技术体系

doi:10.13287/j.1001-9332.202107.036

应用生态学报 ›› 2021, Vol. 32 ›› Issue (7): 2275-2289.doi: 10.13287/j.1001-9332.202107.036

所属专题：于贵瑞院士主编观点

陆地生态系统环境控制实验的研究方法及技术体系

于贵瑞^1,2*, 牛书丽^1,2, 李发东^1,2, 张雷明^1,2, 陈卫楠^1,2

¹中国生态系统研究网络综合研究中心, 中国科学院地理科学与资源研究所生态系统网络观测与模拟重点实验室, 北京 100101;
²中国科学院大学资源与环境学院, 北京 100049

收稿日期:2021-02-23 修回日期:2021-04-01 出版日期:2021-07-15 发布日期:2022-01-15
通讯作者: *yugr@igsnrr.ac.cn
作者简介:于贵瑞,男,1959年生,研究员,博士生导师。主要从事生态学与自然地理学交叉研究。E-mail:yugr@igsnrr.ac.cn
基金资助:
国家自然科学基金项目(31988102,41671045)

Manipulative experiments networks on response and adaptation of terrestrial ecosystems to environmental changes: Building the research methods and technology system

YU Gui-rui^1,2*, NIU Shu-li^1,2, LI Fa-dong^1,2, ZHANG Lei-ming^1,2, CHEN Wei-nan^1,2

¹Synthesis Research Center of Chinese Ecosystem, Key Laboratory of Ecosystem Network Observation and Mode-ling, Institute of Geographic Sciences and Natural Resources Research, Chinese Academy of Sciences, Beijing 100101, China;
²College of Resources and Environment, University of Chinese Academy of Sciences, Beijing 100049, China

Received:2021-02-23 Revised:2021-04-01 Online:2021-07-15 Published:2022-01-15
Contact: *yugr@igsnrr.ac.cn
Supported by:
National Natural Science Foundation of China (31988102,41671045).

摘要/Abstract

摘要： 生物及生态系统与环境变化间的反馈关系及其过程机制是生态学研究的重要内容。不同类型的生物环境因素控制实验以及大尺度的联网野外控制实验被认为是认识生态系统响应和适应环境变化过程机制、精细定量表达的有效手段及认知过程的加速器。近年来发展了大型野外物理模拟实验装置网络(如ECOTRON)、生态系统分析与实验平台(AnaEE)、国际干旱实验研究网络(Drought Network)、氮沉降联合实验网络(Nutrient Network),以及基于各区域性生态观测实验站的联网控制实验(如USA-ILTER)。发展大陆尺度联网实验研究平台事业正日益受到学术界的重视,将会在认知生态系统环境响应过程机制方面发挥更重要的作用。基于以上背景,本文综述了生态系统环境控制实验的研究方法和实验体系的发展,明确指出各种类型的生物环境控制实验需要形成联合协作体系,共同解决生态系统对环境变化的响应及适应的基本科学问题。目前的控制实验包括: 1) 实验室封闭装置内的生物生理生态学控制实验;2) 野外实验场的半开放部分环境要素控制实验;3) 近自然状态的野外环境控制实验;以及4) 基于野外生态站的联网控制实验。进而,本文还深入讨论了陆地生态系统的环境响应及适应过程机制实验系统设计的发展趋势,分析了基于大尺度自然环境梯度实验及生态站尺度的要素控制实验的优势,提出了整合两种实验技术、发展新一代的野外联网实验体系的科学设想,讨论了基于野外联网控制实验的研究体系,论证了研究生态系统对环境变化短期响应和长期适应的规律和机制、生态系统环境响应定量表达的技术途径。若本文提出的控制实验体系设计方案能够得以实施,必将大大促进我国乃至全球生态系统和环境变化科学的研究水平,对我国应对气候变化和生态环境建设具有重要的科学意义。

关键词: 陆地生态系统, 环境变化响应, 环境控制实验, 野外联网控制实验, 中国国家生态系统观测实验研究网络(China EcoNet)

Abstract: The feedback relationship between organisms or ecosystems and environment has been a key issue in ecological research. Manipulative experiments with changing biological or environmental factors and large-scale field experiment networks were regarded as effective approaches to understand and accurately quantify the process and mechanisms underlying ecosystem response and adaptation to environmental changes. In recent years, a few networks have been developed, including large-scale networks of field physics simulation experiment (i.e., ECOTRON), ecosystem analysis and experiment platform (AnaEE), international Drought Network, Nutrient Network, and experiment networks based on regional ecological observation stations (i.e., USA-ILTER) at global scale. The development of continent-scale experiment network platform is attracting more attention from the academic community, and will play a more important role in understanding the process and mechanism underlying ecosystem responses to environmental change. We reviewed the development of method and experiment system of ecosystem manipulative experiments, and clearly pointed out that different experiments should form a joint collaborative system to answer fundamental scientific questions about the response and adaptation of ecosystem to global environment change. Manipulative experiments could be classified into four types: 1) Physiological and ecological experiments in closed laboratory equipment; 2) semi-open experiments with changing environmental factors in the field; 3) near-natural field experiments; 4) experiment networks based on field ecological station. Furthermore, we discussed the trends in network design of manipulative experiments focusing on ecosystem response and adaptation to environmental changes and the advantages of large-scale experiments based on natural environmental gradients. We put forward a proposal of integrating the technical advantages of different types of experiments and developing a new generation of field experiment network system. The study discussed the research system based on field experiment network, demonstrated the possibility to understand the patterns and mechanisms of the ecosystem short-term response and long-term adaptation to environmental changes, and proposed some equations to quantify the environmental response of ecosystems. The application of the design plan of the manipulative experiments network proposed here will greatly promote the scientific research level of ecosystems and environmental changes in China and even over the whole world, which has important scientific significance for the national response to climate change and ecological environmental construction.

Key words: terrestrial ecosystems, environmental change response, environmental manipulative experiments, field experiment network, China EcoNet

于贵瑞, 牛书丽, 李发东, 张雷明, 陈卫楠. 陆地生态系统环境控制实验的研究方法及技术体系[J]. 应用生态学报, 2021, 32(7): 2275-2289.

YU Gui-rui, NIU Shu-li, LI Fa-dong, ZHANG Lei-ming, CHEN Wei-nan. Manipulative experiments networks on response and adaptation of terrestrial ecosystems to environmental changes: Building the research methods and technology system[J]. Chinese Journal of Applied Ecology, 2021, 32(7): 2275-2289.

参考文献

[1] 于振良. 生态学的现状与发展趋势. 北京: 高等教育出版社, 2017 [Yu Z-L. Ecology: Current Knowledge and Future Challenges. Beijing: Higher Education Press, 2017]
[2] 于贵瑞. 陆地生态系统碳氮水耦合循环理论及环境影响的生态学基础—兼论生态系统的科学原理. 北京: 高等教育出版社, 2020 [Yu G-R. Ecological Basis of Carbon-Nitrogen-Water Coupling Cycles and Environmental Influences in Terrestrial Ecosystems: Scientific Principles of Ecosystem. Beijing: Higher Education Press, 2020]
[3] Underwood AJ, Chapman MG, Connell SD. Observations in ecology: You can't make progress on processes without understanding the patterns. Journal of Experimental Marine Biology and Ecology, 2000, 250: 97-115
[4] 于贵瑞, 王秋凤, 杨萌, 等. 生态学的科学概念及其演变与当代生态学学科体系之商榷. 应用生态学报, 2021, 32(1): 1-15 [Yu G-R, Wang Q-F, Yang M, et al. Discussion on the scientific concept of ecology and its evolution and the contemporary ecological discipline system. Chinese Journal of Applied Ecology, 2021, 32(1): 1-15]
[5] 于贵瑞, 杨萌, 陈智, 等. 大尺度陆地生态系统管理的理论基础及其应用研究的思考. 应用生态学报, 2021, 32(3): 771-787 [Yu G-R, Yang M, Chen Z, et al. Thinking on broad-scale terrestrial ecosystem mana-gement and its theoretical fundament and practice. Chinese Journal of Applied Ecology, 2021, 32(3): 771-787]
[6] 于贵瑞. 人类活动与生态系统变化的前沿科学问题. 北京: 高等教育出版社, 2009 [Yu G-R. Scientific Frontier on Human Activities and Ecosystem Changes. Beijing: Higher Education Press, 2009]
[7] Inouye DW. The next century of ecology. Science, 2015, 349: 565
[8] Reiners WA, Lockwood JA, Reiners DS, et al. 100 years of ecology: What are our concepts and are they useful? Ecological Monographs, 2017, 87: 260-277
[9] 牛书丽, 王松, 汪金松, 等. 大数据时代的整合生态学研究——从观测到预测. 中国科学: 地球科学, 2020, 50(10): 1323-1338 [Niu S-L, Wang S, Wang J-S, et al. Integrative ecology in the era of big data: From observation to prediction. Scientia Sinica Terrae, 2020, 50(10): 1323-1338]
[10] 于贵瑞, 杨萌, 陈智, 等. 大尺度区域生态环境治理及国家生态安全格局构建的技术途径和战略布局. 应用生态学报, 2021, 32(4): 1141-1153 [Yu G-R, Yang M, Chen Z, et al. Technical approach and strategic plan for large-scale ecological and environmental governance and national ecological security pattern construction. Chinese Journal of Applied Ecology, 2021, 32(4): 1141-1153]
[11] 于贵瑞, 陈智, 杨萌, 等. 大尺度陆地生态系统科学研究的理论基础及其技术体系与逻辑框架的探讨. 应用生态学报, 2021, 32(2): 377-391 [Yu G-R, Chen Z, Yang M, et al. Discussion on the theoretical basis and technical system of broad-scale terrestrial ecosystem science research. Chinese Journal of Applied Ecology, 2021, 32(2): 377-391]
[12] 于贵瑞, 陈智, 张维康, 等. 试论宏观生态系统科学研究的多学科维度基本问题及其方法学体系. 应用生态学报, 2021, 32(5): 1531-1544 [Yu G-R, Chen Z, Zhang W-K, et al. Discussion on the multi-disciplinary dimensional basic problems and methodological systems of macroecosystem science research. Chinese Journal of Applied Ecology, 2021, 32(5): 1531-1544]
[13] 于贵瑞, 张雷明, 张扬建, 等. 大尺度陆地生态系统状态变化及其资源环境效应的立体化协同联网观测. 应用生态学报, 2021, 32(6): 1903-1918 [Yu G-R, Zhang L-M, Zhang Y-J, et al. A coordinated three-dimensional network for observing large scale terrestrial ecosystem status changes and their resources and environment effects. Chinese Journal of Applied Ecology, 2021, 32(6): 1903-1918]
[14] IPCC. Climate Change and Land: An IPCC Special Report on Climate Change, Desertification, Land Degradation, Sustainable Land Management, Food Security, and Greenhouse Gas Fluxes in Terrestrial Ecosystems. Cambridge, UK: Cambridge University Press, 2019
[15] IPCC. Climate Change 2007: Impacts, Adaptation and Vulnerability. Cambridge, UK: Cambridge University Press, 2007
[16] Newell P, Paterson M. Climate Capitalism: Global Warming and the Transformation of the Global Economy. Cambridge, UK: Cambridge University Press, 2010
[17] Mezbahuddin M, Grant RF, Flanagan LB. Coupled eco-hydrology and biogeochemistry algorithms enable the simulation of water table depth effects on boreal peatland net CO₂ exchange. Biogeosciences, 2017, 14: 5507-5531
[18] Candolin U, Bertell E, Kallio J. Environmental distur-bance alters the ecological impact of an invading shrimp. Functional Ecology, 2018, 32: 1370-1378
[19] Rouphael Y, Petropoulos SA, EI-Nakhel C, et al. Reducing energy requirements in Future Bioregenerative Life Support Systems (BLSSs): Performance and bioactive composition of diverse lettuce genotypes grown under pptimal and suboptimal light conditions. Frontiers in Plant Science, 2019, 10: 1305
[20] Ainsworth EA, Long SP. What have we learned from 15 years of free-air CO₂ enrichment (FACE)? A meta-analytic review of the responses of photosynthesis, canopy properties and plant production to rising CO₂. New Phytologist, 2005, 165: 351-372
[21] Jones AG, Scullion J, Ostle N, et al. Completing the FACE of elevated CO₂ research. Environment International, 2014, 73: 252-258
[22] Norby RJ, Zak DR. Ecological lessons from Free-Air CO₂ Enrichment (FACE) experiments. Annual Review of Ecology, Evolution, and Systematics, 2011, 42: 181-203
[23] Song J, Wan SQ, Piao SL, et al. A meta-analysis of 1,119 manipulative experiments on terrestrial carbon-cycling responses to global change. Nature Ecology & Evolution, 2019, 3: 1309-1320
[24] Hedberg P, Kotowski W, Saetre P, et al. Vegetation recovery after multiple-site experimental fen restorations. Biological Conservation, 2012, 147: 60-67
[25] Wright AJ, Wardle DA, Callaway R, et al. The overlooked role of facilitation in biodiversity experiments. Trends in Ecology & Evolution, 2017, 32: 383-390
[26] Borer ET, Harpole WS, Adler PB, et al. Finding gene-rality in ecology: A model for globally distributed experiments. Methods in Ecology and Evolution, 2014, 5: 65-73
[27] Hanson PJ, Walker AP. Advancing global change bio-logy through experimental manipulations: Where have we been and where might we go? Global Change Biology, 2019, 26: 287-299
[28] Rineau F, Malina R, Beenaerts N, et al. Improving the predictive power and interdisciplinarity of climate change experiments. Nature Climate Change, 2019, 9: 809-816
[29] Dwyer JM, Hobbs RJ, Mayfield MM. Specific leaf area responses to environmental gradients through space and time. Ecology, 2016, 95: 399-410
[30] Lee-Yaw J, Kharouba HM, Bontrager M, et al. A synthesis of transplant experiments and ecological niche models suggests that range limits are often niche limits. Ecology Letters, 19: 710-722
[31] Royer DL, Meyerson LA, Robertson KM, et al. Phenotypic plasticity of leaf shape along a temperature gradient in Acer rubrum. PLoS One, 2009, 4(10): e7653
[32] Glassman SI, Weihe C, Li J, et al. Decomposition responses to climate depend on microbial community composition. Proceedings of the National Academy of Sciences of the United States of America, 2018, 115: 11994-11999
[33] Ineson P, Taylor K, Harrison AF, et al. Effects of climate change on nitrogen dynamics in upland soils. Ⅱ. A transplant approach. Global Change Biology, 2002, 4: 143-152
[34] Salinas N, Malhi Y, Meir P, et al. The sensitivity of tropical leaf litter decomposition to temperature: Results from a large-scale leaf translocation experiment along an elevation gradient in Peruvian forests. New Phytologist, 2011, 189: 967-977
[35] Soderberg DN, Mock KE, Hofstetter RW, et al. Translocation experiment reveals capacity for mountain pine beetle persistence under climate warming. Ecological Monographs, 2020, 91: e01437
[36] Vandvik V, Halbritter AH, Yang Y, et al. Plant traits and vegetation data from climate warming experiments along an 1100 m elevation gradient in Gongga Mountains, China. Scientific Data, 2020, 7: 189
[37] Arnone Ⅲ J, Verburg P, Johnson D, et al. Prolonged suppression of ecosystem carbon dioxide uptake after an anomalously warm year. Nature, 2008, 455: 383-386
[38] Bradford M, Warren Ⅱ R, Baldrian P, et al. Climate fails to predict wood decomposition at regional scales. Nature Climate Change, 2014, 4: 625-630
[39] Parton W, Silver WL. Global-scale similarities in nitrogen release patterns during long-term decomposition. Science, 2007, 315: 361-364
[40] Wardle DA, Bardgett RD, Walker LR, et al. Among- and within-species variation in plant litter decomposition in contrasting long-term chrono sequences. Functional Ecology, 2009, 23: 442-453
[41] Knapp AK, Avolio ML, Beier C, et al. Pushing precipitation to the extremes in distributed experiments: Reco-mmendations for simulating wet and dry years. Global Change Biology, 2017, 23: 1774-1782
[42] Clobert J, Chanzy A, Le Galliard JF, et al. How to integrate experimental research approaches in ecological and environmental studies: AnaEE France as an example. Frontiers in Ecology and Evolution, 2018, 6: 43
[43] He CE, Ouyang Z, Tian ZR, et al. Yield and potassium balance in a wheat-maize cropping system of the North China Plain. Agronomy Journal, 2012, 104: 1016-1022
[44] 陈欣, 张旭东, 宇万太, 等. 坚持土肥高效管理, 促进区域农田生态系统可持续发展. 中国科学院院刊, 2018, 33(9): 992-999 [Chen X, Zhang X-D, Yu W-T, et al. Efficient management on soil and fertilizer to promote sustainable development of local agro-ecosystems in Liaohe plain, China. Bulletin of Chinese Aca-demy of Sciences, 2018, 33(9): 992-999]
[45] 沈彦俊, 胡春胜, 张喜英, 等. 生态学长期研究促进资源高效利用和区域农业可持续发展. 中国科学院院刊, 2018, 33(6): 648-655 [Shen Y-J, Hu C-S, Zhang X-Y, et al. Long-term ecological rsearch (LTER) promotes natural resources use efficiency and agricultural sustainable development in North China Plain. Bulletin of Chinese Academy of Sciences, 2018, 33(6): 648-655]
[46] 徐明岗, 周世伟, 张文菊, 等. 我国土壤肥料长期定位试验与农业可持续生产. 中国科学院院刊, 2015, 30(suppl. 1): 141-149 [Xu M-G, Zhou S-W, Zhang W-J, et al. Long-term soil fertilizer experiments and sustainable agriculture in China. Bulletin of Chinese Aca-demy of Sciences, 2015, 30(suppl.1): 141-149]
[47] Bai Y, Han X, Wu J, et al. Ecosystem stability and compensatory effects in the Inner Mongolia grassland. Nature, 2004, 431: 181-184
[48] Wu J, Naeem S, Elser J, et al. Testing biodiversity-ecosystem functioning relationship in the world's largest grassland: Overview of the IMGRE project. Landscape Ecology, 2015, 30: 1723-1736
[49] 马克平. 生物多样性与生态系统功能的实验研究. 生物多样性, 2013, 21(3): 247-248 [Ma K-P. Studies on biodiversity and ecosystem function via manipulation experiments. Biodiversity Science, 2013, 21(3): 247-248]
[50] 徐炜, 马志远, 井新, 等. 生物多样性与生态系统多功能性: 进展与展望. 生物多样性, 2016, 24(1): 55-71 [Xu W, Ma Z-Y, Jing X, et al. Biodiversity and ecosystem multifunctionality: Advances and perspectives. Biodiversity Science, 2016, 24(1): 55-71]
[51] 李海涛, 廖迎春, 董铭, 等. 田间可调式UV-B辐射增强对籼型杂交稻“协优432”生长及产量的影响. 中国农学通报, 2006, 22(6): 349-349 [Li H-T, Liao Y-C, Dong M, et al. Effects of modulated UV-B supplementation on the growth and yield of rice (Oryza sativa L.) in fields. Chinese Agricultural Science Bulletin, 2006, 22(6): 349-349]
[52] 刘乐, 蔡敏, 陈非洲, 等. 模拟酸雨对不同营养水平湖泊pH值的影响. 生态与农村环境学报, 2018, 34(10): 917-923 [Liu L, Cai M, Chen F-Z, et al. Effects of simulated acid rain on pH in lakes with diffe-rent trophic levels. Journal of Ecology and Rural Environment, 2018, 34(10): 917－923]
[53] Hou R, Ouyang Z, Li Y, et al. Is the change of winter wheat yield under warming caused by shortened reproductive period? Ecology and Evolution, 2012, 2: 2999-3008
[54] Larson C. Losing arable land, China faces stark choice: Adapt or go hungry. Science, 2013, 339: 644
[55] Tu C, Li FD, Qiao YF, et al. Effect of experimental warming on soil respiration under conventional tillage and no-tillage farmland in the North China Plain. Journal of Integrative Agriculture, 2017, 16: 967-979
[56] 侯彦会, 周广胜, 许振柱. 基于红外增温的草地生态系统响应全球变暖的研究进展. 植物生态学报, 2013, 37(12): 1153-1167 [Hou Y-H, Zhou G-S, Xu Z-Z. An overview of research progress on responses of grassland ecosystems to global warming based on infrared heating experiments. Chinese Journal of Plant Ecology, 2013, 37(12): 1153-1167]
[57] 白文明, 周青平, 张文浩. 青藏高原和内蒙古高原草地全球变化生态学控制实验研究比较. 西南民族大学学报: 自然科学版, 2016, 42(4): 355-363 [Bai W-M, Zhou Q-P, Zhang W-H. Comparison of global change ecology between grasslands in Qinghai-Tibet and Inner Mongolia plateau. Journal of Southwest University for Nationalities: Natural Science, 2016, 42(4): 355-363]
[58] 陈美领, 陈浩, 毛庆功, 等. 氮沉降对森林土壤磷循环的影响. 生态学报, 2016, 36(16): 4965-4976 [Chen M-L, Chen H, Mao Q-G, et al. Effect of nitrogen deposition on the soil phosphorus cycle in forest ecosystems: A review. Acta Ecologica Sinica, 2016, 36(16): 4965-4976]
[59] 王迎新, 陈先江, 娄珊宁, 等. 草原灌丛化入侵: 过程、机制和效应. 草业学报, 2018, 27(5): 219-227 [Wang Y-X, Chen X-J, Lou S-N, et al. Woody-plant encroachment in grasslands: A review of mechanisms and aftereffects. Acta Prataculturae Sinica, 2018, 27(5): 219-227]
[60] 倪健, 李宜垠, 张新时. 从生态地理特征论中国东北样带(NECT)在全球变化研究中的科学意义. 生态学报, 1999, 19(5): 622-629 [Ni J, Li Y-Y, Zhang X-S. The scientific significance of the north east China transect (NECT) to global change study by its ecogeographical characteristics. Acta Ecologica Sinica, 1999, 19(5): 622-629]
[61] Gao Q, Yu M, Zhang XS, et al. Dynamic modelling of Northwest China transect responses to global change: A regional vegetation model driven by remote sensing information. Acta Botanica Sinica, 1997, 39: 800-810]
[62] 周广胜, 王玉辉, 蒋延龄. 全球变化与中国东北样带(NECT). 地学前缘, 2002, 9(1): 198-216 [Zhou G-S, Wang Y-H, Jiang Y-L. Global change and water-driven IGBP-NECT Northeast China. Earth Science Frontiers, 2002, 9(1): 198-216]
[63] 任书杰, 于贵瑞, 姜春明, 等. 中国东部南北样带森林生态系统102个优势种叶片碳氮磷化学计量学统计特征. 应用生态学报, 2012, 23(3): 581-586 [Ren S-J, Yu G-R, Jiang C-M, et al. Stoichiometric characteristics of leaf carbon, nitrogen, and phosphorus of 102 dominant species in forest ecosystems along the North-South Transect of East China. Chinese Journal of Applied Ecology, 2012, 23(3): 581-586]
[64] 李正泉, 于贵瑞, 温学发, 等. 中国通量观测网络(ChinaFLUX)能量平衡闭合状况的评价. 中国科学: 地球科学, 2004, 34(suppl. 2): 46-56 [Li Z-Q, Yu G-R, Wen X-F, et al. Evaluation of energy balance closure of ChinaFLUX. Scientia Sinica Terrae, 2004, 34(suppl. 2): 46-56]
[65] 于贵瑞, 张雷明, 孙晓敏, 等. 亚洲区域陆地生态系统碳通量观测研究进展. 中国科学: 地球科学, 2004, 34(suppl. 2): 16-30 [Yu G-R, Zhang L-M, Sun X-M, et al. Advances in carbon fluxes of terrestrial ecosystems in Asia. Scientia Sinica Terrae, 2004, 34(suppl. 2): 16-30]
[66] 于贵瑞, 方华军, 伏玉玲, 等. 区域尺度陆地生态系统碳收支及其循环过程研究进展. 生态学报, 2011, 31(19): 5449-5459 [Yu G-R, Fang H-J, Fu Y-L, et al. Research on carbon budget and carbon cycle of terrestrial ecosystems in regional scale: A review. Acta Ecologica Sinica, 2011, 31(19): 5449-5459]
[67] 牛书丽, 陈卫楠. 全球变化与生态系统——研究现状与展望. 植物生态学报, 2020, 44(5): 449-460 [Niu S-L, Chen W-N. Global change and ecosystems research progress and prospect. Chinese Journal of Plant Ecology, 2020, 44(5): 449-460]

陆地生态系统环境控制实验的研究方法及技术体系

Manipulative experiments networks on response and adaptation of terrestrial ecosystems to environmental changes: Building the research methods and technology system

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	张添佑, 陈智, 温仲明, 于贵瑞. 陆地生态系统临界转换理论及其生态学机制研究进展 [J]. 应用生态学报, 2022, 33(3): 613-622.
[2]	于贵瑞, 张黎, 何洪林, 杨萌. 大尺度陆地生态系统动态变化与空间变异的过程模型及模拟系统 [J]. 应用生态学报, 2021, 32(8): 2653-2665.
[3]	于贵瑞, 张雷明, 张扬建, 杨萌. 大尺度陆地生态系统状态变化及其资源环境效应的立体化协同联网观测 [J]. 应用生态学报, 2021, 32(6): 1903-1918.
[4]	于贵瑞, 陈智, 杨萌, 王秋凤. 大尺度陆地生态系统科学研究的理论基础及其技术体系之探讨 [J]. 应用生态学报, 2021, 32(2): 377-391.
[5]	范珍珍, 王鑫, 王超, 白娥. 整合分析氮磷添加对土壤酶活性的影响 [J]. 应用生态学报, 2018, 29(4): 1266-1272.
[6]	王丽芹1,2,3,齐玉春1,2 **,董云社1,2,彭琴1,2,郭树芳1,2,3,贺云龙1,2,3,闫钟清1,2,3. 冻融作用对陆地生态系统氮循环关键过程的影响效应及其机制 [J]. 应用生态学报, 2015, 26(11): 3532-3544.
[7]	车明亮1,2,陈报章1**,王瑛1,2,郭祥云3. 全球植被动力学模型研究综述 [J]. 应用生态学报, 2014, 25(1): 263-271.
[8]	柳淑蓉,胡荣桂**,蔡高潮. UV-B辐射增强对陆地生态系统碳循环的影响 [J]. 应用生态学报, 2012, 23(07): 1992-1998.
[9]	毛留喜¹;孙艳玲^2,3;延晓冬². 陆地生态系统碳循环模型研究概述 [J]. 应用生态学报, 2006, 17(11): 2189-2195 .
[10]	杨景成, 韩兴国, 黄建辉, 潘庆民. 土地利用变化对陆地生态系统碳贮量的影响 [J]. 应用生态学报, 2003, (8): 1385-1390.
[11]	陈庆强, 沈承德, 孙彦敏, 易惟熙, 姜漫涛, 彭少麟, 李志安. 华南亚热带山地土壤剖面有机质分布特征数值模拟研究 [J]. 应用生态学报, 2003, (8): 1239-1245.
[12]	杨景成, 韩兴国, 黄建辉, 潘庆民. 土地利用变化对陆地生态系统碳贮量的影响 [J]. 应用生态学报, 2003, (8): 1385-1390.
[13]	陈庆强, 沈承德, 孙彦敏, 易惟熙, 姜漫涛, 彭少麟, 李志安. 华南亚热带山地土壤剖面有机质分布特征数值模拟研究 [J]. 应用生态学报, 2003, (8): 1239-1245.
[14]	高全洲, 陶贞. 河流有机碳的输出通量及性质研究进展 [J]. 应用生态学报, 2003, (6): 1000-1002.
[15]	高全洲, 陶贞. 河流有机碳的输出通量及性质研究进展 [J]. 应用生态学报, 2003, (6): 1000-1002.