1964—2015年阿牙克库木湖时序变化的气候响应

doi:10.13866/j.azr.2018.01.11

Abstract

Abstract: In order to analyze the annual, monthly and spatial characteristics of arid lake extent changes under the impacts of climate change, Ayakkul lake in the Alkin mountains is selected as an example to map the lake area changes and level changes with time-series Corona and Landsat imagery in the last 50 years. The results showed that, Ayakkul lake changes are presented as 3 stages: 1964—2004, 2005—2010 and 2011—2014, and the annual area changing rates are -0.012km2/a, -0.256 km2/a and -4.798km2/a, respectively. The overall lake area shrinking mode is from gentle to significant, and the lake water was firstly found extinct on September 25th, 2014, and its ecological function is weaker and weaker. The seasonal characteristic of Chaiwopu lake extent changes are showed as, lake water extent reach its peak in spring and touch its valley in autumn, and the seasonal changes becomes more obvious when the drastic water area changes happen after 2005. Monthly lake area curves showed that Chaiwopu lake is losing its area rapidly year by year. When it comes to lake water level and spatial boundary, their changes match well with the Chaiwopu lake basin topography, which is represented as “rock-ribbed shore and flat bottom”. Before 2005, water area changes are insignificant while lake water level is significant when lake water volume is decreasing. After 2005, lake water boundaries are shrinking. When they are shrinking to the lake bottom in 2012, the underground water levels have high correlations with water area changes. In the wet years between 1999 and 2004, lake shrinking rate is decreasing and Chaiwopu lake keep its dynamic water balance during that period. Exceeding groundwater exploitation after 1993 is the main reason of lake extinction, leading to ecological disaster in this region

Key words: Lake area, Time-series analysis, Temporal and Spatial Changes, Climate Change, Response, Ayakul lake, Xinjiang

Li-Jun-Li, BAI Jie, WANG Ya-Jun. Time series lake area changes of Ayakul Lake and its responses to climate change[J]., 2018, 35(01): 85-95.

References

[1]         张百平，张书清. 大美阿尔金[M].中国大百科全书出版社,2012. [Zhang Baiping, Zhang Shuqing. Grand Beautiful Altun Mountains[M]. Beijing：Encyclopaedia of China Publishing House, 2012.]
[2]         郭敬辉. 新疆水文地理. 北京：科学出版社, 1998: 580. [Guo Jinhui. Xinjiang Hydrological Geography. Beijing: Science Press, 1998: 580.]
[3]         王世江. 中国新疆河湖全书[M]. 北京：中国水利水电出版社, 2011.[Wang Shijiang. Encyclopaedia of Xinjiang Rivers and Lakes[M]. Beijing: China Water&Power Press, 2011.]
[4]         王亚俊, 孙占东. 中国干旱区的湖泊[J]. 干旱区研究，2007，24（4）：424-427．[WangYajun, Sun Zhandong. Lakes in the arid areas in China [J] . Arid Zone Research, 2007，24（4）：424-427. ]
[5]         Bai J, Chen X, Li J, et al. 2011. Changes in the area of inland lakes in arid regions of central Asia during the past 30 years [J]. Environmental Monitoring and Assessment 178(1/4):247-256.
[6]         Lei Y, Yao T, Bird BW, et al. 2013. Coherent lake growth on the central Tibetan Plateau since the 1970s: Characterization and attribution [J]. Journal of Hydrology, 483:61-67.
[7]         Song C Q, Huang B, Ke LH. Modeling and analysis of lake water storage changes on the Tibetan Plateau using multi-mission satellite data [J]. Remote Sensing of Environment, 2013,135:25-35.
[8]         Niu J, Shen C, Li S-G, et al. Quantifying storage changes in regional Great Lakes watershed using a coupled subsurface-land surface process model and GRACE, MODIS products [J]. Water Resources Research, 2014,50(9):7 359-7 377.
[9]         Zhang G, Xie H, Yao T, et al. Quantitative water resources assessment of Qinghai Lake basin using Snowmelt Runoff Model (SRM) [J]. Journal of Hydrology, 2014,519:976-987.
[10]     Zhang G, Yao T, Xie H, Zhang K, Zhu F. Lakes' state and abundance across the Tibetan Plateau[J]. Chinese Science Bulletin, 2014, 59(24):3 010-3 021.
[11]     白洁，陈曦，李均力，等． 1975—2007年中亚干旱区内陆湖泊面积变化遥感分析[J]．湖泊科学，2011，23(1):80-88．[Bai Jie，Chen Xi，Li Junli，et al. Changes of inland lake area in arid Central Asia during 1975-2007：A remote-sensing analysis[J]．Journal of Lake Sciences，2011，23(1)： 80－88.]
[12]     李均力,包安明, 胡汝骥, 等. 亚洲中部干旱区湖泊的地域分异性研究[J]. 干旱区研究, 2013,30(6):961-970. [Li Junli, Bao Anming, Hu Ruji, et al. Remotely sensed mapping and areal differentiation of lakes in Central Asia[J]. Arid Zone Research, 2013,30(6):961-970.]
[13]     朱长明，李均力，张新，等. 近40 a来博斯腾湖水资源遥感动态监测与特征分析[J]. 自然资源学报，2015，30(1)：106-114. [Zhu Changming，Li Junli,Zhang Xin，et al. Bosten water resource dynamic detection and feature analysis in recent 40 years by remote sensing[J]. Journal of Natural Resources. 2015，30(1)：106-114.]
[14]     Harris A R. Time series remote sensing of a climatically sensitive lake [J]. Remote Sensing of Environment, 1994, 50:83-94.
[15]     秦伯强.近百年来亚洲中部内陆湖泊演变及其原因分析[J].湖泊科学，1999，11(1):11-19.[Qing Boqiang.A preliminary investigation of lake evolution in 20-Century in inland mainland Asia with relation to the global warming [J]，Journal of Lake Sciences，1999，11（1）:11-19.]
[16]     胡汝骥，马虹，樊自立，等. 近期新疆湖泊变化所示的气候趋势[J].干旱区资源与环境，2002，16(1)：20-27.[Hu Ruji，Ma Hong，Fan Zili，et al.The climate trend demonstrated by changes of the lakes in Xinjiang in recent years[J]. Journal of Arid Land Resources and Environment,2002,16(1)：20-27.]
[17]     李均力，Sheng Yongwei. 1976-2009年青藏高原内陆湖泊变化的时空格局与过程[J]. 干旱区研究. 2013,23(4):571-581.[Li Junli, Sheng Yongwei. Spatio-temporal pattern and process of inland lake change in the Qinghai-Tibetan plateau during the period of 1976-2009[J]. Arid Zone Research, 2013, 30(4):571-581. ]
[18]     李均力，胡汝骥，黄勇, 等. 1964-2014年柴窝堡湖面积的时序变化及驱动因素[J]. 干旱区研究, 2015, 32(3): 417-427. [Li Junli, Hu Ruji, Huang Yong, et al. Spatial-temporal characterstics of Chaiwopu lake area change and its driving factors from 1964 to 2014[J]. Arid Zone Research, 2015, 32(3): 417-427.]
[19]     Liu J, Kang S, Gong T, Lu A. Growth of a high-elevation large inland lake, associated with climate change and permafrost degradation [J]. Hydrology and Earth System Sciences, 2010, 14:481-489.
[20]     李均力,盛永伟,骆剑承. 喜马拉雅山地区冰湖信息的遥感自动化提取[J]. 遥感学报, 2011,14(1):1-8. [Li Junli, Sheng Yongwei, Luo Jiancheng. Automatic extraction of Himalayan glacial lakes with remote sensing [J]. Journal of Remote Sensing, 2011, 14(1):1-8. ]
[21]     赵煜飞，朱江．近50年中国降水格点日值数据集精度及评估[J]．高原气象,2015,34(1) : 50-58. [Zhao Yufei, Zhu Jiang. Assessing quality of grid daily precipitation datasets in China in recent 50 years [J]. Plateau Meteorology, 2015,34(1): 50-58]
[22]   赵煜飞,朱江,许艳,等. 中国地面降水日值0.5°×0.5°格点数据集[M].北京：国家气象信息中心,2015.[Zhao Yufei, Zhu Jiang, Xu Yan, et al. China 0.5°×0.5° Grid Daily Precipitation Datasets[M].Beijing:National Meteorological Information Cente,2015.]
[23]     王宇, 李均力,李长春,等. 50a年来别珍套山冰湖的时空变化及对气候变化的响应[J]. 干旱区研究，2016，33(3): 299-307. [ Wang Yu, Li Junli, Li Changchun, et al. Spatio-temporal analysis of mountain glacial lakes in Biezhentao Mountains and its response to climate change [J]. Arid Zone Research, 2016, 33(3): 299-307.]
[24]     王苏民, 窦鸿身. 中国湖泊志[M]. 北京:科学出版社, 1998. [Wang Sumin, Dou Hongshen. Chinese Lakes[M]. Beijing: Science Press, 1998.]
[25]     Cheng W, Wang N, Zhao S, et al. Growth of the Sayram Lake and retreat of its water-supplying glaciers in the Tianshan Mountains from 1972 to 2011 [J]. Journal of Arid Land, 2016,8(1): 13-22.
[26]     王宇,李均力，郭木加甫, 等. 1989-2014年赛里木湖水面面积的时序变化特征[J].干旱区地理,2016,39(4):851-860.[ Wang Yu, Li Junli, Guomujiafu, et al. Time-series analysis of Sailimu lake area changes during 1989-2014[J]. Arid Land Geography, 2016,39(4):851-860.]
[27]     李均力，方晖，包安明，等. 近期亚洲中部高山地区湖泊变化的时空分析[J]. 资源科学, 2011, 33(10): 1 021-1 029. [ Li Junli, Fang Hui, Bao Anming, et al. Spatio-temporal analysis of recent changes of lake area and lake water level at high mountains in Central Asia[J]. Resources Science, 2011, 33(10): 1 021-1 029.]
王国亚，沈永平，王宁练，等. 气候变化和人类活动对伊塞克湖水位变化的影响及演化趋势[J].冰川冻土，2010，32(6)：1 097-1 104. [Wang Guoya，Shen Yongping，Wang Ninglian，et al. The effects of climate Change and human activities on the lake level of the Issyk-Kul during the past 100 years[J]. Journal of Glaciology and Geocryology，2010，32(6)：1 097-1 104.]

Time series lake area changes of Ayakul Lake and its responses to climate change

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