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【目的】准确评估水电开发对高海拔生态敏感区的生态环境影响,对于维护该地区的生态安全屏障具有重要意义。基于此,提出一种改进型遥感生态指数(IRSEI)模型研究青藏高原某水电建设对区域生态环境质量的影响。【方法】以青藏高原某水电站为研究对象,鉴于高海拔地区土壤脆弱、地形复杂的生态环境特性,构建归一化差值山地植被指数(NDMVI),同时引入土壤侵蚀模数作为土壤侵蚀指标,提出一种针对高海拔水电开发区的改进型遥感生态指数(IRSEI),采用Theil-Sen斜率估计、Mann-Kendall趋势分析、Hurst指数等方法,评估IRSEI的时空动态及其驱动因素。【结果】IRSEI使用NDMVI替代NDVI并引入土壤侵蚀指标,更适用于地形复杂地区的生态质量监测:水电开发对流域内景观结构造成严重影响,特别是草地和林地,导致其面积降低;IRSEI均值由水电站建设前的0.53下降为建设后的0.42,建设第二年生态质量退化最显著,在运行期回升至0.57;流域林地和草地IRSEI等级主要为优和良,建设用地和耕地等区域主要为差和较差;未来IRSEI发展趋势趋于稳定,维持不变的区域面积占比60%以上;年均降水量、年均温度、NDVI和土地利用类型变化是研究区IRSEI空间分异的主控因子。【结论】工程建设期,水电开发对研究区景观格局和IRSEI造成严重影响。水电站运行期间,研究区生态环境整体呈现良性变化,生态恶化区域主要集中在城镇区域。未来应加强该流域的生态系统治理力度,并综合人类活动和气候变化开展生态保护与修复工作。研究成果可为因地施策落实流域生态保护与高质量发展提供理论依据和数据支持。
Abstract:[Objective]Accurately assessing the ecological and environmental effects of hydropower development in high-altitude, ecologically sensitive regions is essential for maintaining the ecological security barriers of these areas. Therefore, an improved Remote Sensing Ecological Index(IRSEI) model is proposed to study the effect of hydropower construction on regional ecological environment quality in a specific area of the Qinghai-Xizang Plateau.[Methods]Taking a hydropower station in the Qinghai-Xizang Plateau as the study object, and considering the fragile soil and complex topography of high-altitude regions, a normalized difference mountain vegetation index(NDMVI) was established. At the same time, soil erosion modulus was introduced as a soil erosion indicator. An improved remote sensing ecological index(IRSEI) for high-altitude hydropower development areas was proposed. The spatiotemporal dynamics of the IRSEI and its driving factors were analyzed using method such as Theil-Sen slope estimation, Mann-Kendall trend analysis, and Hurst exponent.[Results]By replacing NDVI with NDMVI and incorporating the soil erosion indicator, IRSEI was more suitable for ecological quality monitoring in areas with complex topography. The results showed that hydropower development significantly affected the landscape structure of the basin, particularly grasslands and forests, leading to a reduction in their area. The average IRSEI value decreased from 0.53 before hydropower construction to 0.42 after construction, with the most significant ecological degradation occurring in the second year of construction. During the operational period, the value increased to 0.57. The IRSEI grades of forests and grasslands in the basin were mainly excellent and good, while construction and cultivated land areas were mainly poor and very poor. The future development trend of IRSEI was expected to stabilize, with more than 60% of the basin area remaining unchanged. The main controlling factors for the spatial differentiation of IRSEI in the study area were annual precipitation, average annual temperature, NDVI, and land use changes.[Conclusion]During the construction phase, hydropower development significantly affects the landscape pattern and IRSEI of the study area. During the operation of the hydropower station, the ecological environment of the study area shows an overall positive change, with ecological deterioration mainly concentrated in urban areas. In the future, it is essential to enhance ecological restoration in this basin, taking into account human activities and climate change, and ecological protection and restoration efforts should be carried out. The research findings provide theoretical and data support for implementing targeted ecological protection and promoting high-quality development in the basin.
[1] 秦卫华,刘鲁君,徐网谷,等.小南海水利工程对长江上游珍稀特有鱼类自然保护区生态影响预测[J].生态与农村环境学报,2008,24(4):23-26.QIN W H,LIU L J,XU W G,et al.Prediction of ecological impacts of the planned Xiaonanhai power dam on the rare and endemic fishes nature reserve in the upper reaches of the Yangtze River[J].Journal of Ecology and Rural Environment,2008,24(4):23-26.
[2] PANG M Y,ZHANG L X,BAHAJ A S,et al.Small hydropower development in Tibet:Insight from a survey in Nagqu Prefecture[J].Renewable and Sustainable Energy Reviews,2018,81:3032-3040.
[3] 胡宜刚,李睿,辛玉琴,等.青藏铁路植被恢复和“黑土型” 退化草地治理的实践与启示[J].草业科学,2015,32(9):1413-1422.HU Y G,LI R,XIN Y Q,et al.Management and restoration of degradation vegetation on the Tibetan Plateau[J].Pratacultural Science,2015,32(9):1413-1422.
[4] WAN W,LIU Z,LI K J,et al.Drought monitoring of the maize planting areas in Northeast and North China Plain[J].Agricultural Water Management,2021,245:106636.
[5] 徐涵秋.城市遥感生态指数的创建及其应用[J].生态学报,2013,33(24):7853-7862.XU H Q.A remote sensing Urban ecological index and its application[J].Acta Ecologica Sinica,2013,33(24):7853-7862.
[6] 赵祖伦,赵卫权,苏印,等.1991—2020年贵阳市生态质量演变及空间分异定量归因[J].环境科学,2025,46(1):367-377.ZHAO Z L,ZHAO W Q,SU Y,et al.Spatio-temporal evolution patterns and spatial differentiation attribution of ecological quality in Guiyang from 1991 to 2020[J].Environmental Science,2025,46(1):367-377.
[7] 倪春雨,何文,姚月锋.基于Landsat 8的漓江流域生态环境质量及其影响因素分析[J].科学技术与工程,2024,24(12):5227-5238.NI C Y,HE W,YAO Y F.Analysis of ecological environment quality and its influencing factors of the Lijiang River Basin based on Landsat 8[J].Science Technology and Engineering,2024,24(12):5227-5238.
[8] 白婷,崔涵.基于GEE云计算的祁连山国家自然保护区生态环境质量评价[J].甘肃林业科技,2024,49(1):14-18.BAI T,CUI H.Evaluation of ecological environment quality in Qilian Mountain national nature reserve based on GEE cloud computing[J].Journal of Gansu Forestry Science and Technology,2024,49(1):14-18.
[9] 张云霞.2000—2020年青藏高原生态质量时空变化及其影响因素[D].兰州:兰州大学,2023.ZHANG Y X.Spatiotemporal Changes of Ecological Quality and Its Influencing Factors on the Qinghai-Tibet Plateau from 2000 to 2020[D].Lanzhou:Lanzhou University,2023.
[10] HU Y P,YANG X,GAO X,et al.Analysis of spatio-temporal evolution and driving factors of eco-environmental quality during highway construction based on RSEI[J].Land,2024,13(4):504.
[11] 陈学兄,常庆瑞,毕如田,等.基于山地植被指数估算临县植被覆盖度[J].应用基础与工程科学学报,2020,28(2):310-320.CHEN X X,CHANG Q R,BI R T,et al.Estimation of vegetation coverage based on normalized difference mountain vegetation index (NDMVI) in Lin County,Shanxi Province[J].Journal of Basic Science and Engineering,2020,28(2):310-320.
[12] 杨友刚,雷世兵.青藏高原易贡藏布流域水电开发重大工程地质问题及对策[J].工程地质学报,2024,32(5):1759-1770.YANG Y G,LEI S B.Gigantic engineering geological problems and countermeasures of hydropower development in Yigongzangbu Basin of Tibetan Plateau[J].Journal of Engineering Geology,2024,32(5):1759-1770.
[13] 汪东川,张威,王志恒,等.拉西瓦水电站建设对区域景观格局与生境质量的影响[J].水土保持学报,2021,35(3):200-205.WANG D C,ZHANG W,WANG Z H,et al.Impact of Laxiwa Hydropower Station construction on the regional landscape pattern and habitat quality[J].Journal of Soil and Water Conservation,2021,35(3):200-205.
[14] 刘云龙,何理,聂倩文,等.水电能源开发对雅鲁藏布江流域景观格局的影响[J].水力发电,2020,46(2):1-5.LIU Y L,HE L,NIE Q W,et al.Impact of hydropower development on the landscape pattern of Yarlung Zangbo River Basin[J].Water Power,2020,46(2):1-5.
[15] 王伟,张杰,刘敏,等.水电开发对长江上游生态环境的影响及其对策[J].水力发电,2021,47(1):23-28.WANG W,ZHANG J,LIU M,et al.Impact of hydropower development on the ecological environment in the upper Yangtze River and countermeasures [J].Hydroelectric Power,2021,47(1):23-28.
[16] 宋瑞明,宁亚伟,李敬茹.基于DEM的中小流域数字河网提取与分析[J].中国水利,2022(12):61-64.SONG R M,NING Y W,LI J R.DEM-based extraction and analysis of digital river network in small and medium-sized basins[J].China Water Resources,2022(12):61-64.
[17] 秦璐,陈炳乾,于洋,等.基于遥感生态指数的矿井关闭前后生态环境时空变化规律研究[J].金属矿山,2023(3):242-249.QIN L,CHEN B Q,YU Y,et al.Study on the spatio-temporal variation regularity of ecological environment before and after mine closure based on remote sensing ecological index[J].Metal Mine,2023(3):242-249.
[18] 刘索玄,袁艳斌,赵皞,等.基于遥感生态指数(RSEI)的水电开发区生态环境变化分析:以清江中下游地区为例[J].生态与农村环境学报,2019,35(11):1361-1368.LIU S X,YUAN Y B,ZHAO H,et al.Analysis of ecological environment changes in hydropower development zone based on RSEI:A case study in the middle and lower reaches of the Qingjiang River,China[J].Journal of Ecology and Rural Environment,2019,35(11):1361-1368.
[19] SEN P K.Estimates of the regression coefficient based on Kendall’s tau[J].Journal of the American Statistical Association,1968,63(324):1379-1389.
[20] MASROOR M,REHMAN S,AVTAR R,et al.Exploring climate variability and its impact on drought occurrence:Evidence from Godavari Middle sub-basin,India[J].Weather and Climate Extremes,2020,30:100277.
[21] JIANG L L,GULI·JIAPAER,BAO A M,et al.Vegetation dynamics and responses to climate change and human activities in Central Asia[J].Science of the Total Environment,2017,599:967-980.
[22] WU J F,TAN X Z,CHEN X H,et al.Dynamic changes of the dryness/wetness characteristics in the largest river basin of South China and their possible climate driving factors[J].Atmospheric Research,2020,232:104685.
[23] MOHAMMED I N,BOLTEN J D,SRINIVASAN R,et al.Satellite observations and modeling to understand the Lower Mekong River Basin streamflow variability[J].Journal of Hydrology,2018,564:559-573.
[24] LI J,WANG J L,ZHANG J,et al.Dynamic changes of vegetation coverage in China-Myanmar economic corridor over the past 20 years[J].International Journal of Applied Earth Observation and Geoinformation,2021,102:102378.
[25] MANDELBROT B B,WALLIS J R.Noah,Joseph,and operational hydrology[J].Water Resources Research,1968,4(5):909-918.
[26] ZHU X,WEI S Y,WU Y J.Eco-environmental assessment and trend analysis of the Yangtze River middle reaches megalopolis based on a modified remote sensing ecological index[J].Sustainability,2024,16(18):8118.
[27] 王劲峰,徐成东.地理探测器:原理与展望[J].地理学报,2017,72(1):116-134.WANG J F,XU C D.Geodetector:Principle and prospective[J].Acta Geographica Sinica,2017,72(1):116-134.
[28] 戚梦,陈楠,林偲蔚,等.引入集水区复杂网络的中国地貌识别研究[J].地球信息科学学报,2023,25(5):909-923.QI M,CHEN N,LIN S W,et al.Geomorphic recognition of China considering complex network of catchments[J].Journal of Geo-Information Science,2023,25(5):909-923.
[29] ZHANG X,ZHAO T,XU H,et al.GLC_FCS30D:The first global 30-m land-cover dynamic monitoring product with a fine classification system from 1985 to 2022 using dense time-series Landsat imagery and continuous change-detection method[J].Earth System Science Data Discussions,2023,2023:1-32.
[30] YAN Y M,CAO J X,GU Y F,et al.An evaluation of ecosystem quality and its response to aridity on the Qinghai-Tibet Plateau[J].Remote Sensing,2024,16(18):3461.
[31] PENG X F,ZHANG S Q,PENG P H,et al.Unraveling the ecological tapestry:A comprehensive assessment of Changtang nature reserve’s ecological and environmental using RSEI and GEE[J].Land,2023,12(8):1581.
[32] ARUHO TUSINGWIIRE M,TUMUTUNGIRE M D,SEMPEWO J I,et al.Impacts of climate and land use/cover change on mini-hydropower generation in River Kyambura watershed in South Western part of Uganda[J].Water Practice & Technology,2023,18(6):1576-1597.
[33] YU L,JIA B Y,WU S Q,et al.Cumulative environmental effects of hydropower stations based on the water footprint method:Yalong River Basin,China[J].Sustainability,2019,11(21):5958.
[34] WANG Y K,ZHANG N,WANG D,et al.Investigating the impacts of cascade hydropower development on the natural flow regime in the Yangtze River,China[J].Science of The Total Environment,2018,624:1187-1194.
[35] ALSALEH M,ABDULWAKIL M M,ABDUL-RAHIM A S.Land-use change impacts from sustainable hydropower production in EU28 region:An empirical analysis[J].Sustainability,2021,13(9):4599.
[36] SHI L,FAN H J,YANG L Y,et al.NDVI-based spatial and temporal vegetation trends and their response to precipitation and temperature changes in the Mu Us Desert from 2000 to 2019[J].Water Science and Technology,2023,88(2):430-442.
[37] 张景华,封志明,姜鲁光,等.澜沧江流域植被NDVI与气候因子的相关性分析[J].自然资源学报,2015,30(9):1425-1435.ZHANG J H,FENG Z M,JIANG L G,et al.Analysis of the correlation between NDVI and climate factors in the Lancang River Basin[J].Journal of Natural Resources,2015,30(9):1425-1435.
[38] LIU Q Q,WANG S J,LI B,et al.Dynamics,differences,influencing factors of eco-efficiency in China:A spatiotemporal perspective analysis[J].Journal of Environmental Management,2020,264:110442.
[39] 张庭康,王军邦,叶辉,等.高寒生态系统脆弱性及其对气候变化和人类活动的响应[J].生态学报,2024,44(1):154-170.ZHANG T K,WANG J B,YE H,et al.Vulnerability of alpine ecosystems and its response to climate change and human activities[J].Acta Ecologica Sinica,2024,44(1):154-170.
[40] 贾建辉,陈建耀,龙晓君,等.水电开发对河流生态系统服务的效应评估与时空变化特征分析:以武江干流为例[J].自然资源学报,2020,35(9):2163-2176.JIA J H,CHEN J Y,LONG X J,et al.Evaluating the cumulative impacts of the hydropower development on the river ecosystem services in terms of spatial and temporal aspects:A case study in the mainstream of the Wujiang River[J].Journal of Natural Resources,2020,35(9):2163-2176.
[41] 刘琦,刘世梁,赵清贺,等.漫湾水电站建设的景观生态风险时空分异及影响因子研究[J].安全与环境学报,2012,12(6):113-118.LIU Q,LIU S L,ZHAO Q H,et al.Landscape ecological risk and the influential factors of Manwan Hydropower Station under construction[J].Journal of Safety and Environment,2012,12(6):113-118.
[42] QIN Y,WANG F,ZHANG S Y,et al.Impacts of cascade hydropower development on aquatic environment in middle and lower reaches of Jinsha River,China:A review[J].Environmental Science and Pollution Research,2024,31(42):54363-54380.
[43] WANG J F,WANG X X,JI Y H,et al.Climate factors determine the utilization strategy of forest plant resources at large scales[J].Frontiers in Plant Science,2022,13:990441.
[44] 余慧婕,张方敏,马赫,等.基于遥感生态指数的淮河流域生态环境质量时空演化及其驱动因素分析[J].环境科学,2024,45(7):4112-4121.YU H J,ZHANG F M,MA H,et al.Spatio-temporal evolution and driving factors of ecological environment quality in the Huaihe River Basin based on RSEI[J].Environmental Science,2024,45(7):4112-4121.
基本信息:
DOI:10.13928/j.cnki.wrahe.2025.08.013
中图分类号:TV213;X321
引用信息:
[1]张原,王率,雷俊杰,等.高海拔水电开发对生态环境质量的影响及其驱动因子研究[J].水利水电技术(中英文),2025,56(08):175-191.DOI:10.13928/j.cnki.wrahe.2025.08.013.
基金信息:
青藏高原华能集团在建工程项目(JC2022/D01); 西藏基地与人才项目(XZ202401JD0003); 国家自然科学基金(32271856)