Uncovering the Green, Blue, and Grey Water Footprint and Virtual Water of Biofuel Production in Brazil: A Nexus Perspective

Uncovering the Green, Blue, and Grey Water Footprint and Virtual Water of Biofuel Production in Brazil: A Nexus Perspective

Brazil plays a major role in the global biofuel economy as the world’s second largest producer and consumer and the largest exporter of ethanol. Its demand is expected to significantly increase in coming years, largely driven by national and international carbon mitigation targets. However, biofuel...

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Veröffentlicht in:Sustainability 2017-11, Vol.9 (11), p.2049
Hauptverfasser: Munoz Castillo, Raul, Feng, Kuishuang, Hubacek, Klaus, Sun, Laixiang, Guilhoto, Joaquim, Miralles-Wilhelm, Fernando
Format: Artikel
Sprache:eng
Schlagworte:
Biodiesel fuels
Biofuels
Biomass
Crops
Economics
Ethanol
Food processing
Food production
Greywater
Irrigation
Irrigation water
Land resources
Mitigation
Spatial distribution
Sugarcane
Sustainability
Water availability
Water consumption
Water demand
Water resources
Water scarcity
Water stress
Water supply
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container_end_page
container_issue 11
container_start_page 2049
container_title Sustainability
container_volume 9
creator Munoz Castillo, Raul
Feng, Kuishuang
Hubacek, Klaus
Sun, Laixiang
Guilhoto, Joaquim
Miralles-Wilhelm, Fernando
description Brazil plays a major role in the global biofuel economy as the world’s second largest producer and consumer and the largest exporter of ethanol. Its demand is expected to significantly increase in coming years, largely driven by national and international carbon mitigation targets. However, biofuel crops require significant amounts of water and land resources that could otherwise be used for the production of food, urban water supply, or energy generation. Given Brazil’s uneven spatial distribution of water resources among regions, a potential expansion of ethanol production will need to take into account regional or local water availability, as an increased water demand for irrigation would put further pressure on already water-scarce regions and compete with other users. By applying an environmentally extended multiregional input-output (MRIO) approach, we uncover the scarce water footprint and the interregional virtual water flows associated with sugarcane-derived biofuel production driven by domestic final consumption and international exports in 27 states in Brazil. Our results show that bio-ethanol is responsible for about one third of the total sugarcane water footprint besides sugar and other processed food production. We found that richer states such as São Paulo benefit by accruing a higher share of economic value added from exporting ethanol as part of global value chains while increasing water stress in poorer states through interregional trade. We also found that, in comparison with other crops, sugarcane has a comparative advantage when rainfed while showing a comparative disadvantage as an irrigated crop; a tradeoff to be considered when planning irrigation infrastructure and bioethanol production expansion.
doi_str_mv 10.3390/su9112049
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source MDPI - Multidisciplinary Digital Publishing Institute; EZB-FREE-00999 freely available EZB journals
subjects Biodiesel fuels
Biofuels
Biomass
Crops
Economics
Ethanol
Food processing
Food production
Greywater
Irrigation
Irrigation water
Land resources
Mitigation
Spatial distribution
Sugarcane
Sustainability
Water availability
Water consumption
Water demand
Water resources
Water scarcity
Water stress
Water supply
title Uncovering the Green, Blue, and Grey Water Footprint and Virtual Water of Biofuel Production in Brazil: A Nexus Perspective
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