1990—2021年新疆典型湖泊水量变化遥感估算

doi:10.13287/j.1001-9332.202411.026

应用生态学报 ›› 2024, Vol. 35 ›› Issue (11): 3141-3148.doi: 10.13287/j.1001-9332.202411.026

1990—2021年新疆典型湖泊水量变化遥感估算

陈探^1,2, 赵爽^1,3*, 张大鹏³

¹中国科学院南京地理与湖泊研究所, 中国科学院流域地理学重点实验室, 南京 211135;
²中国科学院南京地理与湖泊研究所湖泊与流域水安全重点实验室, 南京 211135;
³滁州学院地理信息与旅游学院, 安徽滁州 239000

收稿日期:2024-06-23 修回日期:2024-09-08 出版日期:2024-11-18 发布日期:2025-05-18
通讯作者: *E-mail: sz@chzu.edu.cn
作者简介:陈探, 男, 1989年生, 博士。主要从事湖泊流域水文水资源遥感监测研究。E-mail: tanchen@niglas.ac.cn
基金资助:
国家重点研发计划项目(2023YFF1303701)、第三次新疆综合科学考察项目(2022xjkk1504)和国家自然科学基金项目(42277074)

Remote sensing estimation of water volume changes of typical lakes in Xinjiang, China from 1990 to 2021.

CHEN Tan^1,2, ZHAO Shuang^1,3*, ZHANG Dapeng³

¹Key Laboratory of Watershed Geographic Sciences, Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences, Nanjing 211135, China;
²Key Laboratory of Lake and Watershed Science for Water Security, Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences, Nanjing 211135, China;
³School of Geographic Information and Tourism, Chuzhou University, Chuzhou 239000, Anhui, China

Received:2024-06-23 Revised:2024-09-08 Online:2024-11-18 Published:2025-05-18

摘要/Abstract

摘要： 内陆湖泊是中亚干旱区重要的地表水资源。受到自然和人为因素的叠加影响,位于不同位置的干旱区湖泊在不同时期的水文变化特征存在一定差异。然而,该类地区的实测资料匮乏导致难以针对不同的湖泊来开展精细化、长时序的定量水文情势特征监测。本研究基于谷歌地球引擎平台选取1990—2021年完整覆盖新疆典型湖泊——赛里木湖和艾比湖的Landsat 5/7/8遥感影像数据,使用多遥感指数决策树方法提取长时间序列连续的湖泊面积;然后,结合CryoSat-2和ICESat-2测高卫星提取的湖泊水位构建了湖泊面积-水位关系的库容曲线,并估算了湖泊水量变化信息;最后,联合流域水文、气候和人口因子数据,运用相关分析和随机森林方法对比了赛里木湖与艾比湖的水量影响因素。结果表明: 1990—2021年,赛里木湖和艾比湖的水域面积整体均呈扩张趋势,但两个湖泊的水情变化规律不同。赛里木湖面积仅扩张了1.3%,且年际波动较小,水量共增长1.12 km³,增幅为0.04 km³·a^-1;艾比湖面积扩张了30.1%,且年际波动较大,水量的平均变化速率约为0.01 km³·a^-1。年降水和冰川融水是影响赛里木湖水量变化的主要因素,贡献率分别为33%和27%;温度和降水是影响艾比湖水量变化的主要因素,在艾比湖水量变化过程中的贡献率均为28%。本研究旨在利用遥感技术揭示实测资料匮乏的干旱区湖泊动态变化的趋势特征及其对外部环境的响应差异,以期为干旱区的湖泊生态环境及水资源保护提供参考。

关键词: Landsat, 测高卫星, 湖泊水量变化, 库容曲线, 新疆, 湖泊

Abstract: Inland lakes are important surface water resources in arid Central Asia. Due to the superimposed influence of natural factors and human factors, the hydrological characteristics of arid lakes show significant temporal and spatial variations. However, data shortage in this area makes it difficult to carry out detailed and long-term quantitative monitoring of hydrological regimes for different lakes. Based on the Google Earth Engine Platform (GEE), we firstly selected the Landsat 5/7/8 remote sensing image data that completely covered the Saram Lake and Ebinur Lake during 1990-2021, and used the multi-remote sensing index decision tree method to extract the continuous long time series of lake area. Combined with lake water level extracted by CryoSat-2 and ICESat-2 alti-meter satellites, we constructed the storage capacity curve based on the relationship between lake area and water level, and estimated the water volume change information of the lakes. Finally, combined with the hydrological, climate and population factors data of the basin, the correlation analysis and random forest method were used to quantitatively compare and analyze the factors of water quantity variation between the two lakes. The results showed that both Saram Lake and Ebinur Lake had expanded during 1990-2021, though with quite different water conditions. The area of Saram Lake increased by only 1.3%, with little interannual variation. The water volume increased by 1.12 km³ at a growth rate of around 0.04 km³·a^-1. Conversely, the area of Ebinur Lake experienced a 30.1% expansion and exhibited significant annual fluctuation, averaging approximately 0.01 km³·a^-1. Annual precipitation and glacial meltwater were the main factors affecting the water content of the Saram Lake, with contribution rates of 33% and 27%, respectively. However, temperature and precipitation were the main factors affecting the water quantity change of Ebinur Lake, and their contribution rates in the process of water quantity change were both 28%. The aim of this study was to use remote sensing technology to reveal the characteristics of lakes’ dynamic change and the difference of its response to their external environment in arid areas with the shortage of measured data, which would provide scientific reference for lake ecological environment and water resources protection in arid areas.

Key words: Landsat, altimeter satellite, changes in lake volume, curve of storge capacity, Xinjiang, lake

陈探, 赵爽, 张大鹏. 1990—2021年新疆典型湖泊水量变化遥感估算[J]. 应用生态学报, 2024, 35(11): 3141-3148.

CHEN Tan, ZHAO Shuang, ZHANG Dapeng. Remote sensing estimation of water volume changes of typical lakes in Xinjiang, China from 1990 to 2021.[J]. Chinese Journal of Applied Ecology, 2024, 35(11): 3141-3148.

参考文献

[1] An CB, Feng ZD, Barton L. Dry or humid? Mid-Holo-cene humidity changes in arid and semi-arid China. Quaternary Science Reviews, 2006, DOI: 10.1016/J.QUASCIREV.2005.03.013
[2] Bai J, Chen X, Li JL, et al. Changes in the area of inland lakes in arid regions of central Asia during the past 30 years. Environmental Monitoring and Assessment, 2011, 178: 247-256
[3] 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. 湖泊科学, 2011, 23(1): 80-88
[4] 黄金龙, 陶辉, 王艳君, 等. 基于MODIS遥感影像的湖水体面积与水位关系. 农业工程学报, 2012, 28(23): 140-146
[5] 李靖, 李浩, 王树东, 等. 中亚五国主要湖泊水面变化特征及关键影响因素分析. 遥感技术与应用, 2019, 34(3): 639-646
[6] Palmer WC. Meteorological Drought. Washington DC: US Department of Commerce, Weather Bureau, 1965
[7] Brown JF, Wardlow BD, Tadesse T, et al. The vegetation drought response index (VegDRI): A new integra-ted approach for monitoring drought stress in vegetation. GIScience & Remote Sensing, 2008, 45: 16-46
[8] Amani M, Salehi B, Mahdavi S, et al. Temperature-vegetation-soil moisture dryness index (TVMDI). Remote Sensing of Environment, 2017, 197: 1-14
[9] Zhao Y, Liao JJ, Shen GZ, et al. Monitoring lake level changes by altimetry in the arid region of Central Asia. IOP Conference Series: Earth and Environmental Science, 2017, 74: 012004
[10] Yang JM, Ma LG, Li CZ, et al. Temporal-spatial variations and influencing factors of Lakes in inland arid areas from 2000 to 2017: A case study in Xinjiang. Geoma-tics, Natural Hazards and Risk, 2019, 10: 519-543
[11] Mason I, Guzkowska M, Rapley C, et al. The response of lake levels and areas to climatic change. Climatic Change, 1994, 27: 161-197
[12] Martinis S, Plank S, C＇wik K. The use of Sentinel-1 time-series data to improve flood monitoring in arid areas. Remote Sensing, 2018, 10: 583
[13] 柳利利, 韩磊, 韩永贵, 等. 1989—2019年西北地区干燥度指数时空变化及其对气候因子的响应. 应用生态学报, 2021, 32(11): 4050-4058
[14] Xu CC, Chen YN, Chen YP, et al. Responses of surface runoff to climate change and human activities in the arid region of Central Asia: A case study in the Tarim River Basin, China. Environmental Management, 2013, 51: 926-938
[15] Liu HL, Willems P, Bao AM, et al. Effect of climate change on the vulnerability of a socio-ecological system in an arid area. Global and Planetary Change, 2016, 137: 1-9
[16] Zhou YQ, Li YM, Li W, et al. Ecological responses to climate change and human activities in the arid and semi-arid regions of Xinjiang in China. Remote Sensing, 2022, 14: 3911
[17] Li QT, Lu LL, Wang CZ, et al. MODIS-derived spatiotemporal changes of major lake surface areas in arid Xinjiang, China, 2000-2014. Water, 2015, 7: 5731-5751
[18] 魏斌. 新疆艾比湖面积近 45 年动态变化及其驱动机制研究. 博士论文. 山东青岛: 山东科技大学, 2018
[19] 许兴斌, 王勇辉, 姚俊强. 艾比湖流域气候变化及对地表水资源的影响. 水土保持研究, 2015, 22(3): 121-126
[20] 刘艳. 加强赛里木湖生态环境保护保障区域生态安全. 环境与可持续发展, 2016, 41(4): 206-208
[21] 巴音查汗. 艾比湖最低生态水位及生态缺水量研究. 水利规划与设计, 2020(6): 15-17
[22] Liu W, Wu JL, Ma L, et al. A 200-year sediment record of environmental change from Lake Sayram, Tianshan Mountains in China. GFF, 2014, 136: 548-555
[23] 栾瀚韬. 赛里木湖主要理化因子的时空分布及水质评价. 黑龙江科技信息, 2017(4): 137-139
[24] Wang JZ, Ding JL, Li GN, et al. Dynamic detection of water surface area of Ebinur Lake using multi-source satellite data (Landsat and Sentinel-1A) and its responses to changing environment. Catena, 2019, 177: 189-201
[25] 葛娟娟. 基于耦合的艾比湖流域社会经济-生态环境协调研究. 博士论文. 乌鲁木齐: 新疆大学, 2020
[26] Hugonnet R, Mcnabb R, Berthier E, et al. Accelerated global glacier mass loss in the early twenty-first century. Nature, 2021, 592: 726-731
[27] Chen T, Song CQ, Fan CY, et al. A comprehensive data set of physical and human-dimensional attributes for China’s lake basins. Scientific Data, 2022, 9: 1-15
[28] Wulder MA, Roy DP, Radeloff VC, et al. Fifty years of Landsat science and impacts. Remote Sensing of Environment, 2022, 280: 113195
[29] Jiang L, Schneider R, Andersen OB, et al. CryoSat-2 altimetry applications over rivers and lakes. Water, 2017, 9: 211
[30] Tian XX, Shan J. Comprehensive evaluation of the ICESat-2 ATL08 terrain product. IEEE Transactions on Geoscience and Remote Sensing, 2021, 59: 8195-8209
[31] 赵爽, 杨磊库, 刘凯, 等. 基于Sentinel-2 影像的多种水体指数法提取地表水对比研究. 遥感技术与应用, 2024, 39(2): 502-511
[32] Zou ZH, Dong JW, Menarguez MA, et al. Continued decrease of open surface water body area in Oklahoma during 1984-2015. Science of the Total Environment, 2017, 595: 451-460
[33] Wang XX, Xiao XM, Zou ZH, et al. Gainers and losers of surface and terrestrial water resources in China during 1989-2016. Nature Communications, 2020, 11: 3471
[34] Abileah R, Vignudelli S, Scozzari A. A completely remote sensing approach to monitoring reservoirs water volume. International Water Technology Journal, 2011, 1: 63-77
[35] Lu SL, Ouyang NL, Wu BF, et al. Lake water volume calculation with time series remote-sensing images. International Journal of Remote Sensing, 2013, 34: 7962-7973
[36] Cleophas TJ, Zwinderman AH. Modern Bayesian Statistics in Clinical Research. New York: Springer, 2018: 111-118
[37] Breiman L. Random forests. Machine Learning, 2001, 45: 5-32
[38] 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. 干旱区地理, 2016, 39(4): 851-860
[39] 张月, 张飞, 王娟, 等. 近40年艾比湖湿地自然保护区生态干扰度时空动态及景观格局变化. 生态学报, 2017, 37(21): 7082-7097

1990—2021年新疆典型湖泊水量变化遥感估算

Remote sensing estimation of water volume changes of typical lakes in Xinjiang, China from 1990 to 2021.

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