Abstract
Civil infrastructure underpins urban receipts of food, energy, and water (FEW) produced in distant watersheds. In this study, we map flows of FEW goods from watersheds of the contiguous United States to major population centers and highlight the critical infrastructure that supports FEW flows. To do this, we draw upon detailed records of agriculture, electricity, and public water supply production and couple them with commodity flow and infrastructure information. We also compare the flows of virtual water embedded in food and energy commodity flows with physical water flows in inter-basin water transfer projects around the country. We found that the virtual blue water transfers through crops and electricity to major US cities was 53 billion and 8 billion m3 in 2017, respectively, while physical interbasin water transfers for crops, electricity, and public supply water averaged 20.8 billion m3. Highways are the primary infrastructure used to import virtual water associated with food and fuel into cities, although waterways and railways are most utilized for long-distance transport. All of the 204 watersheds in the contiguous US support the food, energy, and/or water supplies of major US cities, with dependencies stretching far beyond each city's borders. Still, most cities source the majority of their FEW and embedded water resources from nearby watersheds. Infrastructure such as water supply dams and inland ports serve as important buffers for both local and supply-chain sourced water stress. These findings can inform efforts to reduce water resources and infrastructure risks in domestic supply chains.
| Original language | English |
|---|---|
| Article number | e2023EF004258 |
| Journal | Earth's Future |
| Volume | 12 |
| Issue number | 6 |
| DOIs | |
| State | Published - Jun 2024 |
| Externally published | Yes |
Funding
L.T.M. acknowledges support from the National Science Foundation Grant CBET-2144169 (“CAREER: Advancing Water Sustainability and Economic Resilience through Research and Education: An Integrated Systems Approach”) and the U.S. Geological Survey Grant/Cooperative Agreement No. G20AP00002 (“Mapping and modeling of interbasin water transfers within the United States”). M.K. was supported by National Science Foundation Grant CBET-1844773 (‘CAREER: A National Strategy for a Resilient Food Supply Chain’) and CBET-2115405(‘SRS RN: Multiscale RECIPES (Resilient, Equitable, and Circular Innovations with Partnership and Education Synergies) for Sustainable Food Systems’), and U.S. Department of Agriculture Grant “Building Resilience to Multiple Shocks: Creating Sustainable Agri-food Systems in the US Midwest Region and Beyond”. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the National Science Foundation or the U.S. Geological Survey. L.T.M. acknowledges support from the National Science Foundation Grant CBET‐2144169 (“CAREER: Advancing Water Sustainability and Economic Resilience through Research and Education: An Integrated Systems Approach”) and the U.S. Geological Survey Grant/Cooperative Agreement No. G20AP00002 (“Mapping and modeling of interbasin water transfers within the United States”). M.K. was supported by National Science Foundation Grant CBET‐1844773 (‘CAREER: A National Strategy for a Resilient Food Supply Chain’) and CBET‐2115405(‘SRS RN: Multiscale RECIPES (Resilient, Equitable, and Circular Innovations with Partnership and Education Synergies) for Sustainable Food Systems’), and U.S. Department of Agriculture Grant “Building Resilience to Multiple Shocks: Creating Sustainable Agri‐food Systems in the US Midwest Region and Beyond”. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the National Science Foundation or the U.S. Geological Survey.
Keywords
- civil infrastructure
- food-energy-water nexus
- virtual water
- water footprint
- water stress
- watersheds