The vulnerability and resilience of a city's water footprint: The case of Flagstaff, Arizona, USA

Rushforth, Richard; Ruddell, Benjamin L.

doi:10.1002/2015wr018006

Cited by 60 publications

(60 citation statements)

References 62 publications

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“…Most studies on VW trade quantify international flows with commodity group resolution typically VW trade estimates that are highly resolved in space provide the greatest opportunity to evaluate links between water scarcity, water resources sustainability, and complex supply chains (Flach et al 2016). For example, VWT resolved to the urban spatial scale enables the quantification of exposure and resilience of cities to direct and indirect water stress (Rushforth and Ruddell 2016). There is significant potential to evaluate high spatial resolution VWT within the US, due to the availability of sub-national empirical transfers (e.g.…”

Section: Spatial Resolutionmentioning

confidence: 99%

“…FAOSTAT, COMTRADE) and the paucity of detailed sub-national trade data is a major limiting factor. Sub-national VW trade studies typically pair VWC with modeled estimates of sub-national commodity transfers (e.g Verma et al 2009, Zhang and Anadon 2014, Dalin et al 2014, Rushforth and Ruddell 2016. or MRIO models (Guan and Hubacek 2007, Dong et al 2014, Zhang and Anadon 2014, Deng et al 2016a, Serrano et al 2016, Ren et al 2018).…”

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confidence: 99%

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Global virtual water trade and the hydrological cycle: patterns, drivers, and socio-environmental impacts

D’Odorico

Carr

Dalin

et al. 2019

Environ. Res. Lett.

149

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The increasing global demand for farmland products is placing unprecedented pressure on the global agricultural system and its water resources. Many regions of the world, that are affected by a chronic water scarcity relative to their population, strongly depend on the import of agricultural commodities and associated embodied (or virtual) water. The globalization of water through virtual water trade (VWT) is leading to a displacement of water use and a disconnection between human populations and the water resources they rely on. Despite the recognized importance of these phenomena in reshaping the patterns of water dependence through teleconnections between consumers and producers, their effect on global and regional water resources has just started to be quantified. This review investigates the global spatiotemporal dynamics, drivers, and impacts of VWT through an integrated analysis of surface water, groundwater, and root-zone soil moisture consumption for agricultural production; it evaluates how virtual water flows compare to the major 'physical water fluxes' in the Earth System; and provides a new reconceptualization of the hydrologic cycle to account also for the role of water redistribution by the hidden 'virtual water cycle'.

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Section: Spatial Resolutionmentioning

confidence: 99%

mentioning

confidence: 99%

Global virtual water trade and the hydrological cycle: patterns, drivers, and socio-environmental impacts

D’Odorico

Carr

Dalin

et al. 2019

Environ. Res. Lett.

149

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“…Konar et al 2011), partly constrained by data availability. However, recent research has begun to evaluate sub-national virtual water transfers (Dalin et al 2014, Dang et al 2015, including those to and from cities (Rushforth and Ruddell 2016), and these studies suggest that hydrological units such as the basin may not always be the appropriate scale at which analysis/prediction is possible. On the one hand, local water scarcity may not significantly impact global markets unless the region contributes to a substantial fraction of global production.…”

Section: Linking Local and Global Scales When Appropriatementioning

confidence: 99%

Prediction in a socio-hydrological world

Srinivasan

Sanderson

Garcia

et al. 2016

Hydrological Sciences Journal

120

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“…A component of indirect water flows, virtual water flows, account for a large volume of water embedded in the food products, fuel resources, and other processed goods that enter an urban environment [ Rushforth and Ruddell , ]. The embedded water in these resources carries important implications for food and water security [ Hoekstra and Chapagain , ; Porkka et al ., ].…”

Section: Introductionmentioning

confidence: 99%

Direct and indirect urban water footprints of the United States

Chini

Konar

Stillwell

2017

Water Resources Research

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The water footprint of the urban environment is not limited to direct water consumption (i.e., municipal supplies); embedded water in imported resources, or virtual water transfers, provides an additional component of the urban water footprint. Using empirical data, our analysis extends traditional urban water footprinting analysis to quantify both direct and indirect urban resources for the United States. We determine direct water volumes and their embedded energy through open records requests of water utilities. The indirect component of the urban water footprint includes water indirectly consumed through energy and food, relating to the food‐energy‐water nexus. We comprehensively quantify the indirect water footprint for 74 metropolitan statistical areas through the combination of various databases, including the Commodity Flow Survey of the U.S. Census Bureau, the U.S. Department of Agriculture, the Water Footprint Network, and the Energy Information Administration. We then analyze spatial heterogeneity in both direct and indirect water footprints, determining the average urban water footprint in the United States to be 1.64 million gallons of water per person per year [6200 m3/person/yr or 17,000 L/person/d], dominated by indirect water. Additionally, our study of the urban water cycle extends beyond considering only water resources to include embedded energy and equivalent carbon dioxide emissions. The inclusion of multiple sectors of the urban water cycle and their underlying processes provides important insights to the overall urban environment, the interdependencies of the food‐energy‐water nexus, and water resource sustainability. Our results provide opportunities for benchmarking the urban energy‐water nexus, water footprints, and climate change potential.

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The vulnerability and resilience of a city's water footprint: The case of Flagstaff, Arizona, USA

Cited by 60 publications

References 62 publications

Global virtual water trade and the hydrological cycle: patterns, drivers, and socio-environmental impacts

Global virtual water trade and the hydrological cycle: patterns, drivers, and socio-environmental impacts

Prediction in a socio-hydrological world

Direct and indirect urban water footprints of the United States

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