Water footprint characteristic of less developed water-rich regions: Case of Yunnan, China

Rapid industrialization and urbanization pose pressure on water resources in China. Virtual water trade proves to be an increasingly useful tool in water stress alleviation for water-scarce regions, while bringing opportunities and challenges for less developed water-rich regions. In this study, Yun...

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Published inWater research (Oxford) Vol. 141; pp. 208 - 216
Main Authors Qian, Yiying, Dong, Huijuan, Geng, Yong, Zhong, Shaozhuo, Tian, Xu, Yu, Yanhong, Chen, Yihui, Moss, Dana Avery
Format Journal Article
LanguageEnglish
Published England Elsevier Ltd 15.09.2018
Subjects
agricultural industry
Agriculture
case studies
China
Commerce
Conservation of Natural Resources - methods
fabrics
Food Industry
Governance
industrialization
Input-output analysis
issues and policy
Manufacturing Industry
socioeconomic development
socioeconomics
Structural decomposition analysis
Technology
trade
Urbanization
virtual water
water
water content
Water footprint
Water management
Water Resources
water security
water stress
Water Supply
Yunnan
China
Structural decomposition analysis
Yunnan
Water management
Governance
Input-output analysis
Water footprint
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Abstract Rapid industrialization and urbanization pose pressure on water resources in China. Virtual water trade proves to be an increasingly useful tool in water stress alleviation for water-scarce regions, while bringing opportunities and challenges for less developed water-rich regions. In this study, Yunnan, a typical province in southwest China, was selected as the case study area to explore its potential in socio-economic development in the context of water sustainability. Both input-output analysis and structural decomposition analysis on Yunnan's water footprint for the period of 2002–2012 were performed at not only an aggregated level but also a sectoral level. Results show that although the virtual water content of all economic sectors decreased due to technological progress, Yunnan's total water footprint still increased as a result of economic scale expansion. From the sectoral perspective, sectors with large water footprints include construction sector, agriculture sector, food manufacturing & processing sector, and service sector, while metal products sector and food manufacturing & processing sector were the major virtual water exporters, and textile & clothing sector and construction sector were the major importers. Based on local conditions, policy suggestions were proposed, including economic structure and efficiency optimization, technology promotion and appropriate virtual water trade scheme. This study provides valuable insights for regions facing “resource curse” by exploring potential socio-economic progress while ensuring water security. [Display omitted] •Both social and economic perspectives should be considered when ensuring local water security.•Water footprint of a less developed water-rich region is analyzed.•Input-output analysis and structural decomposition analysis are used.•Policy suggestions based on local realities are proposed.
AbstractList Rapid industrialization and urbanization pose pressure on water resources in China. Virtual water trade proves to be an increasingly useful tool in water stress alleviation for water-scarce regions, while bringing opportunities and challenges for less developed water-rich regions. In this study, Yunnan, a typical province in southwest China, was selected as the case study area to explore its potential in socio-economic development in the context of water sustainability. Both input-output analysis and structural decomposition analysis on Yunnan's water footprint for the period of 2002-2012 were performed at not only an aggregated level but also a sectoral level. Results show that although the virtual water content of all economic sectors decreased due to technological progress, Yunnan's total water footprint still increased as a result of economic scale expansion. From the sectoral perspective, sectors with large water footprints include construction sector, agriculture sector, food manufacturing & processing sector, and service sector, while metal products sector and food manufacturing & processing sector were the major virtual water exporters, and textile & clothing sector and construction sector were the major importers. Based on local conditions, policy suggestions were proposed, including economic structure and efficiency optimization, technology promotion and appropriate virtual water trade scheme. This study provides valuable insights for regions facing "resource curse" by exploring potential socio-economic progress while ensuring water security.Rapid industrialization and urbanization pose pressure on water resources in China. Virtual water trade proves to be an increasingly useful tool in water stress alleviation for water-scarce regions, while bringing opportunities and challenges for less developed water-rich regions. In this study, Yunnan, a typical province in southwest China, was selected as the case study area to explore its potential in socio-economic development in the context of water sustainability. Both input-output analysis and structural decomposition analysis on Yunnan's water footprint for the period of 2002-2012 were performed at not only an aggregated level but also a sectoral level. Results show that although the virtual water content of all economic sectors decreased due to technological progress, Yunnan's total water footprint still increased as a result of economic scale expansion. From the sectoral perspective, sectors with large water footprints include construction sector, agriculture sector, food manufacturing & processing sector, and service sector, while metal products sector and food manufacturing & processing sector were the major virtual water exporters, and textile & clothing sector and construction sector were the major importers. Based on local conditions, policy suggestions were proposed, including economic structure and efficiency optimization, technology promotion and appropriate virtual water trade scheme. This study provides valuable insights for regions facing "resource curse" by exploring potential socio-economic progress while ensuring water security.
Rapid industrialization and urbanization pose pressure on water resources in China. Virtual water trade proves to be an increasingly useful tool in water stress alleviation for water-scarce regions, while bringing opportunities and challenges for less developed water-rich regions. In this study, Yunnan, a typical province in southwest China, was selected as the case study area to explore its potential in socio-economic development in the context of water sustainability. Both input-output analysis and structural decomposition analysis on Yunnan's water footprint for the period of 2002–2012 were performed at not only an aggregated level but also a sectoral level. Results show that although the virtual water content of all economic sectors decreased due to technological progress, Yunnan's total water footprint still increased as a result of economic scale expansion. From the sectoral perspective, sectors with large water footprints include construction sector, agriculture sector, food manufacturing & processing sector, and service sector, while metal products sector and food manufacturing & processing sector were the major virtual water exporters, and textile & clothing sector and construction sector were the major importers. Based on local conditions, policy suggestions were proposed, including economic structure and efficiency optimization, technology promotion and appropriate virtual water trade scheme. This study provides valuable insights for regions facing “resource curse” by exploring potential socio-economic progress while ensuring water security.
Rapid industrialization and urbanization pose pressure on water resources in China. Virtual water trade proves to be an increasingly useful tool in water stress alleviation for water-scarce regions, while bringing opportunities and challenges for less developed water-rich regions. In this study, Yunnan, a typical province in southwest China, was selected as the case study area to explore its potential in socio-economic development in the context of water sustainability. Both input-output analysis and structural decomposition analysis on Yunnan's water footprint for the period of 2002–2012 were performed at not only an aggregated level but also a sectoral level. Results show that although the virtual water content of all economic sectors decreased due to technological progress, Yunnan's total water footprint still increased as a result of economic scale expansion. From the sectoral perspective, sectors with large water footprints include construction sector, agriculture sector, food manufacturing & processing sector, and service sector, while metal products sector and food manufacturing & processing sector were the major virtual water exporters, and textile & clothing sector and construction sector were the major importers. Based on local conditions, policy suggestions were proposed, including economic structure and efficiency optimization, technology promotion and appropriate virtual water trade scheme. This study provides valuable insights for regions facing “resource curse” by exploring potential socio-economic progress while ensuring water security. [Display omitted] •Both social and economic perspectives should be considered when ensuring local water security.•Water footprint of a less developed water-rich region is analyzed.•Input-output analysis and structural decomposition analysis are used.•Policy suggestions based on local realities are proposed.
Author Zhong, Shaozhuo
Dong, Huijuan
Geng, Yong
Qian, Yiying
Tian, Xu
Chen, Yihui
Yu, Yanhong
Moss, Dana Avery
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  organization: Department of Geography, Faculty of Environmental Studies, University of Waterloo, 200 University Avenue West, Waterloo, Ontario, N2L 3G1, Canada
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Keywords Structural decomposition analysis
Yunnan
Water management
Governance
Input-output analysis
Water footprint
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Snippet Rapid industrialization and urbanization pose pressure on water resources in China. Virtual water trade proves to be an increasingly useful tool in water...
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SubjectTerms agricultural industry
Agriculture
case studies
China
Commerce
Conservation of Natural Resources - methods
fabrics
Food Industry
Governance
industrialization
Input-output analysis
issues and policy
Manufacturing Industry
socioeconomic development
socioeconomics
Structural decomposition analysis
Technology
trade
Urbanization
virtual water
water
water content
Water footprint
Water management
Water Resources
water security
water stress
Water Supply
Yunnan
Title Water footprint characteristic of less developed water-rich regions: Case of Yunnan, China
URI https://dx.doi.org/10.1016/j.watres.2018.03.075
https://www.ncbi.nlm.nih.gov/pubmed/29793160
https://www.proquest.com/docview/2045268364
https://www.proquest.com/docview/2574313993
Volume 141
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