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遥感技术与应用  2016, Vol. 31 Issue (6): 1223-1230    DOI: 10.11873/j1004-0323.issn.6.1223..2016
地理信息系统     
青藏高原冰川、积雪与地质灾害空间观测研究态势分析
安培浚,高峰,王立伟
(中国科学院兰州文献情报中心,甘肃 兰州 730000)
Status and Trends of Space Observation Research on Glacier,Snow and Geological Disasters on the Qinghai-Tibet Plateau
An Peijun,Gao Feng,Wang Liwei
(Lanzhou Library and Information Centre of the Chinese Academy of Sciences,Lanzhou 730000,China)
 全文: PDF(4386 KB)  
摘要:

气候变化带来的一系列严重问题越来越成为人类关注的焦点。21 世纪初启动的世界气候研究计划(WCRP)新的核心计划——气候与冰冻圈计划(Climate and Cryosphere,CliC),使得冰冻圈研究成为国际热点的标志。由于青藏高原冰川积雪对气候变化的敏感性,以及地质灾害常发的特殊性,近年来中国、印度、美国、日本、德国等国家部署了一系列研究计划和研究项目,发表了大量的青藏高原冰川、积雪和地质灾害空间观测机理与应用的论文。通过文献计量分析这些论文可以反映出国际上青藏高原冰川、积雪与地质灾害空间观测研究的进展和发展态势。以SCIE中检索到的2000~2015年间与青藏高原冰川、积雪与地质灾害空间观测研究相关的论文、研究综述和学术会议论文等相关文献为基础,分析了国际地球关键带研究的总体研究概况、主要研究主体(国家和机构)分布和不同时期的研究主题和热点、学科领域分布、研究合作及未来发展态势等特征。

关键词: 青藏高原冰川积雪地质灾害空间观测遥感    
Abstract:

A series of serious problems caused by climate change have becoming a focus.In the early 21th century,a new core plan of World Climate Research Program (WCRP),Climate and Cryosphere (CliC) was initiated,as marked Cryosphere research as an international research hotspot.Due to sensitivity of glacier and snow on Qinghai\|Tibet on climate change,possible influence of geological disasters on the surrounding countries,China,India,the United States,Japan and Germany arranged and carried out a series of research plans and projects in recent years,and published lots of papers about mechanism and application of spatial observation of glacier,snow and geological disasters on the Tibet Plateau.Bibliometrical analysis can reveal related research progress and trend.In this paper,SCIE retrieved the relevant papers,research reviews,conference papers and other relevant documents from 2001 to 2015.The overall of study,the major research subject (countries and institutions) and hot spots in different periods,distribution of subjects,research cooperation and future development trend and other features were analyzed.

Key words: Qinghai-Tibet Plateau    Glacier    Snow    Geological disaster    Spatial observation    Remote sensing
收稿日期: 2016-01-30 出版日期: 2016-12-30
:  TP 79  
基金资助:

中国科学院青年创新促进会(Y4AC011001)资助。

作者简介: 安培浚(1979-),女,山西应县人,副研究员,主要从事地球科学战略情报研究、信息分析。Email:anpj@llas.ac.cn。
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引用本文:

安培浚,高峰,王立伟. 青藏高原冰川、积雪与地质灾害空间观测研究态势分析[J]. 遥感技术与应用, 2016, 31(6): 1223-1230.

An Peijun,Gao Feng,Wang Liwei. Status and Trends of Space Observation Research on Glacier,Snow and Geological Disasters on the Qinghai-Tibet Plateau. Remote Sensing Technology and Application, 2016, 31(6): 1223-1230.

链接本文:

http://www.rsta.ac.cn/CN/10.11873/j1004-0323.issn.6.1223..2016        http://www.rsta.ac.cn/CN/Y2016/V31/I6/1223

[1]Gore A.An Inconvenient Truth[M].Rodale:Emmaus,2006:328.

[2]Owen L A,Thackray G,Anderson R S,et al.Integrated Research on Mountain Glaciers:Current Status,Priorities Andfuture Prospects[J].Geomorphology,2009,103(2):158-171.[3]IPCC.IPCC Fourth Assessment Report:Climate Change 2007[R].IPCC,Geneva,Switzerland,2007.

[4]Bolch T,Buchroithner M F,Pieczonka T,et al.Planimetric Andvolumetric Glacier Changes in Khumbu Himalayas Since 1962 Using Corona,Landsat TM and ASTER Data[J].Journal of Glaciology,2008,54(187):592-600.

[5]Haeberli W,Hoelzle M,Paul F,et al.Integrated Monitoring of Mountain Glaciers as Key Indicators of Global Climatechange:the European Alps[J].Annals of Glaciology,2007,46:150-160.

[6]Lu Anxin,Yao Tandong,Liu Shiyin,et al.Glacier Change in the Geladandong Area of the Tibetan Platea Monitored by Remote Sensing[J].Journal of Glaciology and Geocryolog,2002,24(5):559-562.[鲁安新,姚檀栋,刘时银,等.青藏高原各拉丹冬地区冰川变化的遥感监测[J].冰川冻土,2002,24(5):559-562.]

[7]Min Wenbin,Li Bin.Review and Prospect on the Application of Meteorological Satellite Data over Tibetan Plateau in the Past 20 Years[J].Journal of Sichuan Meteorology,2011,31 (3):83-88.[闵文彬,李宾.近20年青藏高原气象卫星应用研究回顾与展望[J].高原山地气象研究,2011,31(3):83-88.]

[8]Qin Dahe,Xiao Cunde,Ding Yongjian,et al.Progress on Cryospheric Studies by International and Chinese Communities and Perspectives[J].Quarterly Journal of Applied Meteorology,2006,17(6):649-656.[秦大河,效存德,丁永建,等.国际冰冻圈研究动态和我国冰冻圈研究的现状与展望[J].应用气象学报,2006,17(6):649-656.]

[9]Shi Yafeng.Evolution of the Cryosphere in the Tibetan Platean,China,and its Relationship with the Global Change in the Mid Quaternary[J].Journal of Glaciology and Geocryology,1998,20(3):197-208[施雅风.第四纪中期青藏高原冰冻圈的演化及其与全球变化的联系[J].冰川冻土,1998,20(3):197-208.]

[10]Yao Tandong,Zhu Liping.The Response of Environmental Changes on Tibetan Plateau to Global Changes and Adaptation Strategy[J].Advances in Earth Science,2006,21(5):459-464.[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.]

[11]Yang Meixue,Yao Tandong.A Review of the Study on the Impact of Snow Cover in the Tibetan Plateau on Asian Monsoon[J].Journal of Glaciology and Geocryology,1998,20(2):186-190.[杨梅学,姚檀栋.青藏高原雪盖对亚洲季风影响研究进展[J].冰川冻土,1998,20(2):186-190]

[12]Paul F,Ka¨a¨b A,Maisch M,et al.The New Remote-sensing-derived Swiss Glacier Inventory:I.Methods[J].Annals of Glaciology,2002,34(1):355-361.

[13]Ye Qinghua,Chen Feng,Yao Tandong.Tupu of Glacier Variations Western Himalayas,in the Mt.NaimonaNyi Region,in the Last Three Decades[J].Journal of Remote Sensing,2007,11(4):511-520.[叶庆华,陈锋,姚檀栋,等.近30年来喜马拉雅山脉西段纳木那尼峰地区冰川变化的遥感监测研究[J].遥感学报,2007,11(4):511-520.]

[14]Zhang Minghua.Extracting the Temperate Glacier Information in the Mount Namjagbarwa,Tibet Autonomous Region based on ETM+ Image[J].Journal of Glaciology and Geocryology,2005,(2):226-232.[张明华.基于影像的西藏南迦巴瓦峰地区海洋性冰川信息提取[J].冰川冻土,2005,(2):226-232.]〖JP〗

[15]K b A.Monitoring High-mountain Terrain Deformation from Repeated Air-and Spaceborne Optical Data:Examples Using Digital Aerial Imagery and ASTER Data[J].ISPRS Journal of Photogrammetry and Remote Sensing,2002,57(1):39-52.


 

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