Evaluation of water resources utilization in Guizhou Province based on water footprint theory and LMDI model
-
摘要: 基于水足迹理论构建区域水资源利用评价指标体系,分析贵州省2000-2017年水足迹时间变化,并采用LMDI模型探讨人口、经济和技术等驱动因素对水足迹变化的影响程度。结果表明:贵州省总水足迹经历了先波动增长后减少再逐渐增加的过程;水资源自给率年均达到97%以上,对外依赖程度较低;水足迹经济效益值逐年增加明显,水足迹土地密度与总水足迹变化趋势一致,而万吨水足迹人口密度则与总水足迹变化趋势相反;水资源压力指数整体维持在40%以上,其中偏枯水年和枯水年水资源压力指数大于70%;人文驱动因素对水足迹变化的影响程度:经济效应>技术效应>人口效应,自然驱动因素中降水量是导致水足迹变化的主要因素。Abstract: Guizhou Province is located in southwest China with a total land area of about 176,000 km2, accounting for 1.8% of the China’s land area. Karst landforms are widely distributed in this region with a large area of peak-clusters and depressions, forming a unique karst ecosystem. This region has subtropical humid monsoon climate, featured by notable spatial and temporal differences of precipitation. As a typical karst region, it has water resource vulnerability, manifested by low water storage capacity, frequent seasonal drought, and the water environment is easily polluted and difficult to recover. In recent years, the engineering water shortage problem has been significantly improved with the comprehensive progress of large-scale water source project construction in Guizhou Province. In order to evaluate current situation of water resources utilization and the driving factors affecting water use in Guizhou Province, this work established a water resources utilization evaluation index system, based on the water footprint theory; and the analysis of temporal changes of the water footprints from 2000 to 2017 was carried out. The LMDI model was used to examine the impact extent of population, economic and technological driving factors on the changes of the water footprints. The results show that the total water footprint of Guizhou Province has experienced a process of growth from fluctuant to decreasing one and then gradually increase. The self-sufficiency rate of water resources is more than 97% per year, and the degree of external dependence is low; the economic benefit value of water footprints increases year by year. Water footprint land density is consistent with the trend of total water footprint. However, the population density of 10,000 tons of water footprint is inconsistent with the trend of total water footprint. The overall pressure index of water resources is maintained above 40%, of which the water stress index of semi-dry and dry years is greater than 70%. Based on the LMDI model, the impact degree of anthropogenic driving factors on the changes of water footprint, is in the order of economic effect>technical effect>population effects. Among them, economic effects account for 53.22% of the impact, while technical effects contribute 46.1% and population effects are only 0.68%. Precipitation as a main natural driving factor is also leading the changes in water footprint.
-
Key words:
- water footprint /
- assessment system /
- LMDI model /
- driving factors /
- Guizhou Province
-
[1] 钱逸颖,董会娟,田旭,等.应对水资源危机的中国水足迹研究综述[J].生态经济,2018,34(7):162-166,173. [2] A Y Hoekstra,A K Chapagain . Water footprints of nations: Water use by people as a function of their consumption pattern[J]. Water Resources Management,2007,21(1):35-48. [3] Marston L,Ao Y,Konar M,et al. High-Resolution Water Footprints of Production of the United States[J]. Water Resources Research,2018,54(3):2288-2316. [4] Chen Z M,Chen G Q.Virtual water accounting for the globalized world economy: National water footprint and international virtual water trade[J].Ecological Indicators,2013,28:142-149. [5] Chapagain A K , Hoekstra A Y.The blue, green and grey water footprint of rice from production and consumption perspectives[J]. Ecological Economics, 2011, 70(4):749-758. [6] Xinchun C,Mengyang W,Rui S,et al. Water footprint assessment for crop production based on field measurements: A case study of irrigated paddy rice in East China.[J]. Science of the Total Environment, 2018,610(1):84-93. [7] 周玲玲,王琳,余静.基于水足迹理论的水资源可持续利用评价体系:以即墨市为例[J].资源科学, 2014,36(5):913-921. [8] 刘楚烨,赵言文,马群宇,等.基于水足迹理论的江苏省水资源可持续利用评价[J].水土保持通报,2017,37(6):313-320. [9] 何开为,张代青,侯瑨,等.基于水足迹理论的云南省农业水资源承载力DEA模型评价[J].资源与水工程学报,2015,26(4):126-131. [10] 杨江州,许幼霞,周旭,等.贵州喀斯特高原水资源压力时空变化分析[J].人民珠江,2017,38(7):27-31. [11] 刘丽颖,杨清伟,曾一笑,等.喀斯特地区水资源安全评价模型构建及其应用:以贵州省为例[J].中国岩溶,2018,37(2):203-210. [12] 周亮广, 梁虹. 喀斯特地区水资源承载力评价研究:以贵州省为例[J]. 中国岩溶, 2006, 25(1):23-28 [13] 苏印,官冬杰,苏维词.基于SPA的喀斯特地区水安全评价:以贵州省为例[J].中国岩溶,2015,34(6):560-569 [14] 郭晓娜. 西南喀斯特区水资源脆弱性评价[D].重庆:重庆师范大学,2017. [15] 贵州省水利厅.贵州省水资源公报(2000-2017)[EB /OL]. [16] 贵州省统计局.贵州省统计年鉴[Z].北京:中国统计出版,2018. [17] 戚瑞,耿涌,朱庆华.基于水足迹理论的区域水资源利用评价[J].自然资源学报,2011,26(3):486-495. [18] Ang B W, Zhang F Q, Choi K H. Factorizing changes in energy and environmental indicators through decomposition[J]. Energy, 1998, 23(6):489-495. [19] 杨洋,丁镭,曾克峰.基于LMDI模型的广西水足迹驱动力分析[J]. 国土资源科技管理,2017, 34(2):20-29. [20] 王云飞.基于水足迹理论的太原市水资源利用评价分析[J].黄河水利职业技术学院学报,2018,30(2):11-16. [21] 潘文俊,曹文志,王飞飞,等.基于水足迹理论的九龙江流域水资源评价[J].资源科学,2012,34(10):1905-1912. [22] 奚旭,孙才志,赵良仕.基于IPAT-LMDI的中国水足迹变化驱动力分析[J].水利经济,2014,32(5):1-5,71. -
点击查看大图
计量
- 文章访问数: 1779
- HTML浏览量: 581
- PDF下载量: 364
- 被引次数: 0
下载:
