中国省区虚拟水流动及对农业用水的影响

doi:10.3969/j.issn.1674-8530.18.1025

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摘要模拟省区间粮食虚拟水流动格局的基础上,从节水效应和对区域用水效率的改变2方面评价虚拟水流动对中国农业用水的影响.粮食虚拟水呈由北向南流动的总体格局,其中黑龙江与吉林贡献了虚拟水输出量的69.1%,广东、浙江、福建及上海占流入总量的56.2%;虚拟水在全国范围内节约了199.4亿m³的水资源;虚拟水流动提高了全部输入区的单位产品耗水(WFP)和用水量(WUP)和主要输入区的WFP,降低了除黑龙江、吉林之外所有输出区的WUP和WFP.各省区应根据自身状况和在虚拟水流动中的地位制定水资源高效利用与管理策略.其中,东北粮食主产区应从区域视角发展节水农业,提高农业的水资源利用效率.

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	郭相平

	余涛
	吴梦洋
	高爽
	操信春
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关键词 ：虚拟水, 农业用水效率, 节水效应, 粮食安全

Abstract：Based on simulating the virtual water flow among provinces, the effect of virtual water flow on agricultural water use in China was evaluated from the perspectives of water-saving effect and regional water use efficiency. The results show that the virtual water of food flows from north to south on the whole. Heilongjiang and Jilin account for 69.1% of the tatal output, Guangdong, Zhejiang, Fujian, and Shanghai account for 56.2% of the total input. Meanwhile, the virtual water flow among provinces has saved 199.4 millions m³ of water resources in China, the WFP and WUP in the whole input regions and the WFP in the main input regions are increased, the WUP and WFP in all output regions except Heilongjiang and Jilin are descended. All the provinces, cities and autonomous regions should formulate strategies for the effective utilization and management of water resources based on their respective local condition and goal orientation, the main grain-producing areas in Northeast China should develop regional water-saving agriculture and improve the efficiency of agriculture water use.

Key words： virtual water agricultural water use efficiency water-saving effect food security

收稿日期: 2018-04-11

基金资助:

国家自然科学基金资助项目(51609065);江苏省社会科学基金资助项目(17GLC013);江苏省水利科技项目

引用本文:

郭相平^,, 余涛, 吴梦洋, 高爽, 操信春^,*. 中国省区虚拟水流动及对农业用水的影响[J]. 排灌机械工程学报, 2018, 36(8): 744-749. GUO Xiangping^,, YU Tao, WU Mengyang, GAO Shuang, CAO Xinchun^,*. Virtual water flow and its impact on agricultural water utilization among provinces of China. Journal of Drainage and Irrigation Machinery Engin, 2018, 36(8): 744-749.

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http://zzs.ujs.edu.cn/pgjx/CN/10.3969/j.issn.1674-8530.18.1025 或 http://zzs.ujs.edu.cn/pgjx/CN/Y2018/V36/I8/744

[1]VÖRÖSMARTY C J, MCINTYRE P B, GESSNER M O, et al. Global threats to human water security and river biodiversity[J]. Nature, 2010, 467(7315): 555-561.
[2]操信春, 任杰, 吴梦洋, 等. 基于水足迹的中国农业用水效果评价[J].农业工程学报, 2018, 34(5): 1-8.
　　CAO Xinchun, REN Jie, WU Mengyang, et al. Asses-sing agricultural water use effect of China based on water footprint framework[J]. Transactions of the CSAE, 2018, 34(5): 1-8.(in Chinese)
[3]WANG Y, WU P, ENGEL B A, et al. Comparison of volumetric and stress-weighted water footprint of grain products in China [J]. Ecological indicators, 2015, 48: 324-333.
[4]操信春, 邵光成, 王小军, 等. 中国农业广义水资源利用系数及时空格局分析[J]. 水科学进展, 2017, 28(1): 14-21.
　　CAO Xinchun, SHAO Guangcheng,WANG Xiaojun,et al.Generalized water efficiency and strategic implications for food security and water management: a case study of grain production in China[J].Advances in water science, 2017, 28(1): 14-21.(in Chinese)
[5]SHTULL-TRAURING E, BERNSTEIN N. Virtual water flows and water-footprint of agricultural crop production, import and export: a case study for Israel[J]. Science of the total environment, 2018, 622:1438-1447.
[6]YANG H, WANG L, ABBASPOUR K, et al. Virtual water trade: an assessment of water use efficiency in the international food trade[J]. Hydrology and earth system sciences discussions, 2006, 10(3): 443-454.
[7]FADER M, GERTEN D, THAMMER M, et al. Internal and external green-blue agricultural water footprints of nations, and related water and land savings through trade[J]. Hydrology & earth system sciences, 2011, 8(1):483-527.
[8]TAMEA S, ALLAMANO P, CARR J A, et al. Local and global perspectives on the virtual water trade[J]. Hydrology & earth system sciences, 2013, 17(3):1205-1215.
[9]WANG Y, SUN S, ENGEL B A, et al. Application of water footprint combined with a unified virtual crop pattern to evaluate crop water productivity in grain production in China[J]. Science of the total environment, 2014, 497: 1-9.
[10]SUN S, WANG Y, ENGEL B, et al. Effects of virtual water flow on regional water resource stress: a case study of grain in China [J]. Science of the total environment, 2016, 550: 871-879.
[11]WANG Y, LIU D, CAO X, et al. Agricultural water rights trading and virtual water export compensation coupling model: a case study of an irrigation district in China[J]. Agricultural water management, 2017, 180:99-106.
[12]DALIN C, HANASKI N, QIU H, et al. Water resources transfers through Chinese interprovincial and foreign food trade [J]. Proceedings of the National Academy of Sciences of the United States of America, 2014, 111(27): 9774-9779.
[13]TAMEA S, LAIO F, RIDOLFI L. Global effects of local food-production crises: a virtual water perspective[J]. Scientific reports, 2016, 6:18803.
[14]MONTESINOS P, CAMACHO E, CAMPOS B, et al. Analysis of virtual irrigation water. Application to water resources management in a Mediterranean river basin[J]. Water resources management, 2011, 25(6):1635-1651.
[15]WANG Y, WU P, ZHAO X, et al. Virtual water flows of grain within China and its impact on water resource and grain security in 2010[J]. Ecological engineering, 2014, 69: 255-264.
[16]操信春. 中国粮食生产用水效率及其时空差异研究[D]. 杨凌: 西北农林科技大学, 2015.