收稿日期: 2006-04-21
修回日期: 2006-04-29
网络出版日期: 2006-05-15
基金资助
国家重点基础研究发展计划项目“青藏高原形成演化及其环境资源效应”(编号:G1998040800)资助.
The Response of Environmental Changes on Tibetan Plateau to Global Changes and Adaptation Strategy
Received date: 2006-04-21
Revised date: 2006-04-29
Online published: 2006-05-15
青藏高原的环境变化对全球变化具有敏感响应和强烈影响。青藏高原的现代环境与地表过程相互作用,引起包括冰冻圈和水资源以及生态系统等方面的一系列变化,对高原本身以及周边地区的人类生存环境和经济社会发展产生重大影响。作为国际研究的热点地区,青藏高原环境变化研究目前出现三个新的科学动向:关注关键地区的关键科学问题的系统研究;关注以现代地表过程为核心的监测研究;关注全球变化影响下的圈层相互作用研究。本项目的研究对青藏高原环境变化科学的发展、国际科学前沿的贡献以及服务于社会经济发展,都具有十分重要的意义。通过项目的研究将揭示青藏高原隆升到现代地貌与环境格局过程中所出现的重大构造事件和环境事件;重建不同区域、不同时间尺度的气候环境变化序列并揭示其时空分布特征;阐明青藏高原冰冻圈、湖泊和主要生态系统与土地覆被在不同气候条件下的变化特征;揭示青藏高原环境变化与地表过程对全球变化的响应特点和高原热力与动力过程对不同气候系统变化的影响。本项目将在高原南北典型区域利用地貌学与沉积学手段,研究青藏高原现代地貌与环境格局的形成过程;利用湖芯、冰芯、树木年轮等手段,研究青藏高原过去环境变化的特征事件、区域分异及其与全球变化的联系;利用冰川、冻土、积雪的时空变化,结合对高原特殊大气边界层的观测,研究青藏高原冰冻圈变化与能量水分循环过程;从冰川、湖泊、大气的监测入手,结合模式方法,研究青藏高原环境变化的机制;利用生态系统碳的源—汇变化,研究青藏高原生态系统对环境变化的响应;综合研究全球变化背景下青藏高原环境变化与水资源变化所产生的区域效应和适应对策。
姚檀栋 , 朱立平 . 青藏高原环境变化对全球变化的响应及其适应对策[J]. 地球科学进展, 2006 , 21(5) : 459 -464 . DOI: 10.11867/j.issn.1001-8166.2006.05.0459
The environmental changes of Tibetan Plateau possess sensitive response and strong effect to global changes. The interaction between modern environment and land surface processes on the plateau induces a series of variations in the cryosphere, water resources and ecological system, which produce important influence on the human living circumstance and economic-society development on the plateau itself and periphery regions. As a region focused by international scientific research, the plateau experienced three developing stages. The first is focusing the systemic studies of the key problems in the key areas, the second is focusing the monitoring studies centered with surface processes, and the third is focusing the interactions among different spheres influenced by global changes. This project possesses very important significance to the study of environmental changes on Tibetan Plateau and the contribution for international scientific frontier as well as local economics-society development. In this project, a series of objectives are planned to be achieved: discovering key tectonic and environmental events from the plateau's formation to its present landform structures; reconstructing climatic and environmental sequences with different time scales in different areas and clarifying their space-time features; elucidating the variation characteristics of cryosphere, lakes, dominant ecosystems and land covers under different climatic conditions on the plateau; revealing the responses of the environmental changes and land surface processes of the plateau to global changes, and the effects of the plateau's thermo and dynamical processes to different climatic systems. Some methods and contents are performed in this project: By using geomorphologic and sedimentary methods, we study the formation processes of present landform and environment frames. By collecting lake cores, ice cores and tree rings, we study key events during the past environment changes and their linkages to global changes. By analyzing the space-time variations of glaciers, permafrost and snow accumulations together with observation of boundary layers, we study the variations of cryosphere and cycling processes of energy and water. By monitoring the glaciers, lakes and atmosphere together with using climatic models, we study the potential mechanism of environmental changes. By detecting the variations of carbon sources and sinks in the dominant ecosystems, we study the response of the main ecosystem to environmental changes. By a series of integrated analyses, we study the effects of the environmental changes and water sources changes on the Tibetan Plateau and adaptation strategies under global changes.
[1] Kutzbach J E, Prell W L, Ruddiman W F. Sensitivity of Eurasian Climate to surface uplift of the Tibetan Plateau[J]. Journal of Geology,1993,101:177-190.
[2] 孙鸿烈, 郑度.青藏高原综合科学考察研究的回顾与展望[C]∥郑度等主编.青藏高原形成环境与发展. 石家庄: 河北科学技术出版社, 2003.
[3] Guo Z T, Ruddiman W, Hao Q Z, et al. Onset of Asian desertifications by 22Myr ago inferred from loess deposits in China[J]. Nature,2002,416:159-163.
[4] Fang X M, Carmala G, Rob V, et al. Flexural subsidence by 29 Ma on the NE edge of Tibet from the magnetostratigraphy of Linxia Basin,China[J]. Earth and Planetary Science Letters,2003,210:545-560.
[5] Liu X D, Yin Z Y. Sensitivity of East Asian monsoon climate to the uplift of the Tibetan Plateau. Palaeogeography[J]. Palaeoclimatology, Palaeoecology,2002,183:223-245.
[6] 姚檀栋, 徐柏青, 段克勤, 等.青藏高原达索普冰芯2 ka来温度和甲烷浓度变化记录[J].中国科学:D辑,2002,32(4):346-352.
[7] Zhu Liping, Wang Junbo, Chen Ling, et al. 20,000-year environmental change reflected by Multidisciplinary Lake sediments in Chen Co, Southern Tibet[J]. Acta Geographica Sinica,2004,59(4):514-524.[朱立平,王君波,陈玲,等.藏南沉错湖泊沉积多指标揭示的二万年以来环境变化[J].地理学报,2004,59(4):514-524.]
[8] Thompson L G, Mosley-Thompson E, Davis M E, et al. Tropical glacier and ice core evidence of climate change on annual to millennial time scales[J]. Climatic Change,2002,59:137-155.
[9] 施雅风,刘时银.中国冰川对21世纪全球变暖响应的预估[J].科学通报,2000,45(4):434-438.
[10] Meier M F, Dyurgerov M B. How Alaska affects the world[J]. Science,2002,297:350-351.
[11] Wang S L, Niu F J, Zhao L, et al. The thermal stability of roadbed in permafrost regions along Qinghai-Tibet Highway[J]. Cold Regions Science and Technology,2003,37:25-34.
[12] Chen Guichen, Huang Zhiwei, Lu Xuefeng, et al. Characteristics of wetland and its conservation in the Qinghai Plateau[J]. Journal of Glaciology and Geocryology,2002,24(3):254-259.[陈桂琛, 黄志伟, 卢学峰, 等. 青海高原湿地特征及其保护[J].冰川冻土,2002,24(3):254-259.]
[13] Klein J A, Harte J, Zhao X Q. Experimental warming causes large and rapid species loss, dampened by simulated grazing, on the Tibetan Plateau[J]. Ecology Letters,2004,7(12):1 170-1 179.
[14] 郑度,姚檀栋,等.青藏高原隆升与环境效应[M]. 北京: 科学出版社,2004.
[15] Bollasina M, Benedict S. The role of the Himalayas and the Tibetan Plateau within the Asian monsoon system[J]. Bulletin of the American Meteorological Society,2004,85(7):1 001.
[16] Wu Guoxiong, Liu Yimin, Liu Xin, et al. How the heating over the Tibetan Plateau affects the Asian climate in summer[J]. Chinese Journal of Atmospheric Sciences,2005,29(1):47-56.[吴国雄, 刘屹岷, 刘新, 等.青藏高原加热如何影响亚洲夏季的气候格局[J]. 大气科学,2005,29(1):47-56.]
[17] 方小敏, 韩永翔, 马金辉, 等. 青藏高原沙尘特征与高原黄土堆积: 以2003-03-04拉萨沙尘天气过程为例[J]. 科学通报,2004,49(11):1 084-1 090.
[18] Wu T W, Qian Z G. The relation between the Tibetan winter snow and the Asian summer monsoon and rainfall: An observational investigation[J]. Journal of Climate,2003,16:2 038-2 051.
[19] 苏珍, 施雅风. 小冰期以来中国季风温冰川对全球变暖的响应[J]. 冰川冻土,2000,22(3):223-229.
[20] Rea D K, Snoeckx H, Joseph L H. Late Cenozoic eolian deposition in the northern Pacific: Asian drying, Tibet uplift, and cooling of the northern hemisphere[J]. Palaeoceanography,1998,13:215-224.
[21] Raymo M E, Ruddiman W F, Froelich P N. Influence of late Cenozoic mountain building on ocean geochemical cycles[J]. Geology,1988,16:649-653.
[22] Moore III B. Meeting tomorrow's challenges[J]. IGBP News Letter,1999,38:2.
[23] Chen Yiyu, Chen Panqin, Ge Quansheng, et al. Global change research: Progress and prospect[J]. Earth Science Frontiers,2002,9(1):11-18.[陈宜瑜,陈泮勤,葛全胜,等.全球变化研究进展与展望[J]. 地学前缘,2002,9(1):11-18.]
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