2000-2018年间青藏高原植被覆盖变化及其与气候因素的关系分析

doi:10.11733/j.issn.1007-0435.2019.06.023

草地学报 ›› 2019, Vol. 27 ›› Issue (6): 1651-1658.DOI: 10.11733/j.issn.1007-0435.2019.06.023

2000-2018年间青藏高原植被覆盖变化及其与气候因素的关系分析

韩炳宏^1,2,4, 周秉荣^2,3, 颜玉倩^2,3, 石明明^2,3, 苏淑兰^2,3, 赵恒和^2,4, 牛得草⁵, 傅华⁵

1. 中国气象局成都高原气象研究所, 四川成都, 610072;
2. 青海省防灾减灾重点实验室, 青海西宁, 810001;
3. 青海省气象科学研究所, 青海西宁, 810001;
4. 青海省海南州气象局, 青海共和, 813099;
5. 兰州大学草地农业生态系统国家重点实验室, 甘肃兰州, 730020

收稿日期:2019-08-02 修回日期:2019-09-20 出版日期:2019-12-15 发布日期:2019-12-31
通讯作者: 周秉荣,E-mail:zbr0515@foxmail.com
作者简介:韩炳宏(1988-),男,甘肃会宁人,硕士,助理工程师,主要从事草地生态遥感与气候变化方面的研究,E-mail:hanbh13@lzu.edu.cn
基金资助:
国家重点研发计划（2016YFC0501903）资助

Analysis of Vegetation Coverage Change and Its Driving Factors over Tibetan Plateau From 2000 to 2008

HAN Bing-hong^1,2,4, ZHOU Bing-rong^2,3, YAN Yu-qian^2,3, SHI Ming-ming^2,3, SU Shu-lan^2,3, ZHAO Heng-he^2,4, NIU De-cao⁵, FU Hua⁵

1. Institute Plateau Meteorology, CMA, Chengdu, Sichuan Province 610072, China;
2. Key Laboratory of Disaster Prevention and Mitigation of Qinghai Province, Xining, Qinghai Province 810001, China;
3. Institute of Meteorological Science of Qinghai Province, Xining, Qinghai Province 810001, China;
4. Meteorological bureau of Hainan Tibetan autonomous prefecture, Gonghe, Qinghai Province 813099, China;
5. State Key Laboratory of Grassland Agro-ecosystem, College of Pastoral Agriculture Science and Technology, Lanzhou University, Lanzhou, Gansu Province 730020, China

Received:2019-08-02 Revised:2019-09-20 Online:2019-12-15 Published:2019-12-31

摘要/Abstract

摘要： 探讨全球气候变化背景下青藏高原地区植被覆盖变化及其驱动因素，对加深全球气候变化的认识和生态环境保护具有重要的生态价值和现实意义。本研究利用2000-2018年中尺度分辨率成像光谱归一化植被指数（Moderate Resolution Imaging Spectroradiometer Normalized Difference Vegetation Index，MODIS NDVI）1 km·月^-1分辨率数据以及气象观测数据，采用最大合成法、趋势性分析以及相关分析方法，探讨了青藏高原地区NDVI的时空变化趋势及其与气温、降水的关系。结果表明，近19a来，青藏高原地区NDVI呈增加趋势。从地理单元来看，低植被覆盖区主要分布于西藏大部、新疆南部和甘南局部以及青海西北部；中植被覆盖区主要位于青海与甘肃、西藏、四川和云南的交汇区域；高植被覆盖区主要分布在四川和云南西北部、青海和甘南以及藏东南局地。除局部地区植被有所退化，大部地区植被生长良好，且植被改善的面积大于植被退化。因此，青藏高原植被整体呈稳定恢复状态。青藏高原地区NDVI与同期气温和降水均显著相关，但与气温的关系更密切。气温每升高1℃，NDVI增加0.128；降水每增加100 mm，NDVI增加0.172。

关键词: 青藏高原, 植被覆盖, 降水, 气温, 驱动因素

Abstract: Studing vegetation coverage change and its driving factors over the Tibetan Plateau under the context of global climate change has an important ecological value and practical significance,and contributes to understanding global climate change and ecological environment protection deeply. Using the monthly moderate resolution imaging spectroradiometer normalized difference vegetation index,(MODIS NDVI) with 1 km resolution from 2000 to 2018,and meteorological observation data,this study analyzed the spatio-temporal variation trends of the NDVI and its relationship with precipitation and temperature over the Tibetan Plateau based on maximum value composites (MVC),linear trends and correlation analysis method. The results showed that NDVI of the Tibetan Plateau had been increasing over the past 19 years. From the perspective of geographical units,the low vegetated areas mainly distributed in most parts of Tibet,parts of Xinjiang and Gansu,and parts of northwest Qinghai. The area of medium vegetation coverage mainly located in the intersection of Qinghai,Gansu,Tibet,Sichuan and Yunnan. The high vegetation coverage area mainly distributed in Sichuan and most parts of Yunnan,Qinghai and Gansu as well as some parts of southeastern Tibet. Only a small part of vegetation over Tibetan Plateau was still degrading,most of them had been improved,the total area of improved vegetation growth in the whole Tibetan Plateau was larger than that of degraded. Therefore,the vegetation of Tibetan Plateau was in a steady state of recovery. NDVI was significantly correlated with temperature and precipitation over the same period,but it is more closely correlated with temperature than precipitation. NDVI increased 0.128 per 1℃ increase in temperature and increased 0.172 per 100 mm increase in precipitation.

Key words: Tibetan Plateau, Vegetation coverage, Precipitation, Temperature, Driving factors

中图分类号:

Q948.156

韩炳宏, 周秉荣, 颜玉倩, 石明明, 苏淑兰, 赵恒和, 牛得草, 傅华. 2000-2018年间青藏高原植被覆盖变化及其与气候因素的关系分析[J]. 草地学报, 2019, 27(6): 1651-1658.

HAN Bing-hong, ZHOU Bing-rong, YAN Yu-qian, SHI Ming-ming, SU Shu-lan, ZHAO Heng-he, NIU De-cao, FU Hua. Analysis of Vegetation Coverage Change and Its Driving Factors over Tibetan Plateau From 2000 to 2008[J]. Acta Agrestia Sinica, 2019, 27(6): 1651-1658.

0
/ / 推荐

导出引用管理器 EndNote|Ris|BibTeX

链接本文: https://manu40.magtech.com.cn/Jweb_cdxb/CN/10.11733/j.issn.1007-0435.2019.06.023

https://manu40.magtech.com.cn/Jweb_cdxb/CN/Y2019/V27/I6/1651

参考文献

[1] 朴世龙,方精云. 1982-1999年我国陆地植被活动对气候变化响应的季节差异[J]. 地理学报,2003,58(11):119-125
[2] Seddon A W R,Macias-Fauria M,Long P R,et al. Sensitivity of global terrestrial ecosystems to climate variablity[J]. Nature,2016,53(17593):229-232
[3] 曹博,张勃,马彬,等. 2000-2014年甘肃省NDVI时空变化特征[J]. 中国沙漠,2018,38(2):418-427
[4] 李璠,徐维新. 2000-2015年青海省不同功能区NDVI时空变化分析[J]. 草地学报,2017,25(4):701-710
[5] 阿迪来﹒乌甫,玉素甫江﹒如素力,热伊莱﹒卡得尔,等. 新疆焉耆盆地LAI反演及空间分布特征[J]. 中国沙漠,2016,36(5):1340-1347
[6] Myneni R B,Keeling C D,Tucker C J,et al. Increased plant growth in the northern high latitudes from 1981to 1991[J]. Nature,1997,38(66626):698-702
[7] 方精云,朴世龙,贺金生,等. 近20年来中国植被活动在增强[J]. 中国科学,2003,33(6):554-565
[8] 李双双,延军平,万佳. 近10年陕甘宁黄土高原区植被覆盖时空变化特征[J]. 地理学报,2012,67(7):960-970
[9] Piao S L,Wang X H,Ciais P,et al. Changes in satellite-derived vegetation growth trend in temperate and boreal Eurasia from 1982 to 2006[J]. Global Change Biology,2011,17(10):3228-3239
[10] Mohammat A,Wang X H,Xu X T,et al. Drought and spring cooling induced recent decrease in vegetation growth in Inner Asia[J]. Agriculture and Forest Meteorology,2013,(178):21-30
[11] 杜加强,贾尔恒·阿哈提,赵晨曦,等. 1982-2012年新疆植被NDVI的动态变化及其对气候变化和人类活动的响应[J]. 应用生态学报,2015,26(12):3567-3578
[12] 孙鸿烈,郑度,姚檀栋,等. 青藏高原国家生态安全屏障保护与建设[J]. 地理学报,2012,67(1):3-12
[13] 张镱锂,李兰晖,丁明军,等. 新世纪以来青藏高原绿度变化及动因[J]. 自然杂志,2017,39(3):173-178
[14] Yao T,Wu F,Ding L,et al. Multispherical interactions and their effects on the Tibetan Plateau's Earth system:A review of the recent researches[J]. National Science Review,2015,2(4):468-488
[15] Shen M G,Piao S L,Jeong S,et al. Evaporative cooling over the Tibetan Plateau induced by vegetation growth[J]. Proceedings of the National Academy of Sciences,2015,112(30):9299-9304
[16] 丁明军,张镱锂,刘林山,等. 1982-2009年青藏高原草地覆盖度时空变化特征[J]. 自然资源学报,2010,25(12):2114-2122
[17] 赵紫薇. 1982-2013年青藏高原植被动态变化时序分析[J]. 测绘科学,2017,42(6):62-70
[18] 孟梦,牛铮,马超,等. 青藏高原NDVI变化趋势及其对气候的响应[J]. 水土保持研究,2018,25(3):360-365
[19] 卓嘎,陈思蓉,周兵. 青藏高原植被覆盖时空变化及其对气候因子的响应[J]. 生态学报,2018,38(9):3208-3218
[20] Stow D,Hope A,McGuire D,et al.Remote sensing of vegetation and land-cover change in Arctic Tundra Ecosystems[J].Remote Sensing of Environment,2004,89:281-308
[21] Hope A,Boynton W,Stow D,et al.Inter-annual growth dynamics of vegetation in the Kuparuk River watershed based onthe normalized difference vegetation index[J]. InternationalJournal of Remote Sensing,2003,24(17):3413-3425
[22] 申广荣,王人潮. 植被光谱遥感数据的研究现状及其展望[J]. 浙江大学学报(农业与生命科学版),2001,27(6):682-690
[23] Shabanov N,Zhou L,Knyazikhin Y,et al.Analysis of inter-annual changes in northern vegetation activity observed inAVHRR data from 1981 to 1994[J].IEEE Transactions onGeoscience and Remote Sensing,2002,40(1):115-130
[24] 徐慧. 基于SPOT VEGETATION数据的长江流域植被覆盖变化特征分析[D]. 武汉:华中农业大学,2011
[25] 宋怡,马明国. 基于SPOT VEGETATION数据的中国西北植被覆盖变化分析[J]. 中国沙漠,2007,27(1):89-93
[26] Shen M G,Tang Y H,Chen J,et al. Influences of temperature and precipitation before the growing season on spring phenology in grasslands of the central and eastern Qinghai-Tibetan Plateau[J]. Agricultural and Forest Meteorology,2011,151(12):1711-1722
[27] Zhang L,Guo H D,WangC,et al. The long-term trends (1982-2006) in vegetation greenness of the alpine ecosystem in the Qinghai-Tibetan Plateau[J]. Environmental Earth Sciences,2014,72(6):1827-1841
[28] Zhang G L,Zhang Y J,Dong J W,et al. Green-up dates in the Tibetan Plateau have continuously advanced from 1982 to 2011[J]. Proceedings of the National Academy of Sciences,2013,110(11):4309-4314

2000-2018年间青藏高原植被覆盖变化及其与气候因素的关系分析

Analysis of Vegetation Coverage Change and Its Driving Factors over Tibetan Plateau From 2000 to 2008

PDF

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]	黄小涛, 姚步青, 马真, 周华坤. 青海高原草地净初级生产力和降水利用效率时空特征[J]. 草地学报, 2021, 29(S1): 19-26.
[2]	李若玮, 叶冲冲, 王毅, 韩国栋, 孙建. 基于InVEST模型的青藏高原碳储量估算及其驱动力分析[J]. 草地学报, 2021, 29(S1): 43-51.
[3]	兰翔宇, 叶冲冲, 王毅, 曾涛, 孙建. 1995—2014年青藏高原水源涵养功能时空演变特征及其驱动力分析[J]. 草地学报, 2021, 29(S1): 80-92.
[4]	姚喜喜, 王立亚, 严振英, 李泉林, 王有彬, 马秉云, 雷延民, 周睿, 谢久祥. 青藏高原典型草地牧草营养品质和消化率特征及其相关性[J]. 草地学报, 2021, 29(S1): 113-120.
[5]	张中华, 马丽, 周秉荣, 宋明华, 徐文华, 邓艳芳, 王芳, 佘延娣, 张骞, 姚步青, 马真, 周华坤. 高寒草甸优势种功能多样性对增温和模拟放牧的响应[J]. 草地学报, 2021, 29(S1): 225-232.
[6]	王谭国艳, 马志远, 李沛洋, 郭俊宏, 张嘉懿, 蒋胜竞. 短期增温对青藏高原高寒草甸不同植物根际丛枝菌根真菌的影响[J]. 草地学报, 2021, 29(9): 1959-1966.
[7]	郭文章, 井长青, 王公鑫, 侯志雄, 赵苇康. 天山北坡荒漠草原土壤呼吸和生态系统呼吸对降水的响应[J]. 草地学报, 2021, 29(9): 2031-2039.
[8]	顾锡羚, 郭恩亮, 银山, 王永芳, 那仁满都拉, 万志强. 干旱对内蒙古植被生长的累积与滞后影响评估研究[J]. 草地学报, 2021, 29(6): 1301-1310.
[9]	杨洁, 单立山, 苏铭, 张正中, 解婷婷, 李毅. 降水量和生长方式对红砂和珍珠根系形态特征的影响研究[J]. 草地学报, 2021, 29(5): 936-945.
[10]	何国兴, 韩天虎, 柳小妮, 张德罡, 李强, 孙斌, 潘冬荣, 刘志刚, 关文昊, 杨军银. 甘肃省草地植被NDVI时空变化特征及驱动因素研究[J]. 草地学报, 2021, 29(5): 1004-1013.
[11]	杨阳, 章妮, 蒋莉莉, 陈克龙. 青海湖高寒草地土壤理化性质及微生物群落特征对模拟降水的响应[J]. 草地学报, 2021, 29(5): 1043-1052.
[12]	魏星星, 吴江琪, 李广, 王海燕, 刘帅楠, 张世康, 张娟. 青藏高原湿草甸土壤氮组分对氮添加浓度的响应[J]. 草地学报, 2021, 29(4): 677-683.
[13]	马小林, 侯庆丰, 杨鼎. 退耕还草对青海省农牧民家庭收入的影响[J]. 草地学报, 2021, 29(4): 772-779.
[14]	张鹏, 李毅, 单立山, 解婷婷. 降水变化对混生红砂-珍珠生物量及分配的影响[J]. 草地学报, 2021, 29(3): 478-487.
[15]	饶品增, 王义成, 王芳. 三江源植被覆盖区NDVI变化及影响因素分析[J]. 草地学报, 2021, 29(3): 572-582.