Publications

Naugle, Asmeret B.; Backus, George A.; Tidwell, Vincent C.; Keller, Elizabeth J.; Villa, Daniel V.

Abstract not provided.

Tidwell, Vincent C.

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Naugle, Asmeret B.; Backus, George A.; Tidwell, Vincent C.; Keller, Elizabeth J.

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Tidwell, Vincent C.

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Kobos, Peter H.; Tidwell, Vincent C.; Moreland, Barbie; Zhai, Haibo Z.; Rubin, Ed R.

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Brown, Theresa J.; Vugrin, Eric D.; Tidwell, Vincent C.; Verzi, Stephen J.; Moore, Thomas M.; Finley, Patrick D.; Beyeler, Walter E.; Corbet, Thomas F.

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Tidwell, Vincent C.

Abstract not provided.

Sandia journal manuscript; Not yet accepted for publication

Tidwell, Vincent C.

Energy production requires water, while the conveyance, storage, and treatment of water requires energy—this is the energy-water nexus. The importance of this nexus has recently been highlighted by droughts reducing hydropower production, heat waves impacting stream water temperatures forcing nuclear and coal-fired power plants to suspend operations, floods and hurricanes damaging energy infrastructure, and the denial of new power plant permits due to limited water availability. All this while the energy intensity of the water sector is increasing as water is moved from more distant locations and increasing water treatment is required. Tackling this energy-water nexus will require significant coordination between water and energy managers from the local to the federal level.

Tidwell, Vincent C.; Wolfsberg, Andrew W.; Macknick, Jordan M.; Middleton, Richard M.

In the Southwest and Southern Rocky Mountains (SWSRM), energy production, energy resource extraction, and other high volume uses depend on water supply from systems that are highly vulnerable to extreme, coupled hydro-ecosystem-climate events including prolonged drought, flooding, degrading snow cover, forest die off, and wildfire. These vulnerabilities, which increase under climate change, present a challenge for energy and resource planners in the region with the highest population growth rate in the nation. Currently, analytical tools are designed to address individual aspects of these regional energy and water vulnerabilities. Further, these tools are not linked, severely limiting the effectiveness of each individual tool. Linking established tools, which have varying degrees of spatial and temporal resolution as well as modeling objectives, and developing next-generation capabilities where needed would provide a unique and replicable platform for regional analyses of climate-water-ecosystem-energy interactions, while leveraging prior investments and current expertise (both within DOE and across other Federal agencies).

Tidwell, Vincent C.

Abstract not provided.

Tidwell, Vincent C.; Silver, Emily J.

Abstract not provided.

Lowry, Thomas S.; Kobos, Peter H.; Malczynski, Leonard A.; Tidwell, Vincent C.; Roach, Jesse D.; McMahon, Kevin A.

This paper is the output from SNL's involvement in the Western Area Power Administration (WAPA), the Colorado River Energy Distributors Association (CREDA), and the Upper Colo rado River Commission's (UCRC) sponsored Phase II work to establish market and non - market valu es (NMV's) of water and hydropower asso ciated with Glen Canyon Dam (GCD) operations and the Colorado River ecosystem. It describes the purpose and need to develop a systems model for the Colorado River Basin that includes valuations in the economic, hydrologic, environmental, social, and cultural sectors . It outlines the benefits and unique features associated with such a model and provides a roadmap of how a syste ms model would be developed and implemented. While not meant to serve as a full development plan, the ideas and concepts herein represent what the Sandia National Laboratories (SNL) research team believes is the most impac tful and effective path forward to address an ever increasing complex set of problems that occur at the basin - scale and beyond .

Environmental Science and Technology

Tidwell, Vincent C.; Moreland, Barbie; Zemlick, Katie

A significant fraction of our nation's electricity use goes to lift, convey, and treat water, while the resulting expenditures on electricity represent a key budgetary consideration for water service providers. To improve understanding of the electricity-for-water interdependency, electricity used in providing water services is mapped at the regional, state and county level for the 17-conterminous states in the Western U.S. This study is unique in estimating electricity use for large-scale conveyance and agricultural pumping as well as mapping these electricity uses along with that for drinking and wastewater services at a state and county level. Results indicate that drinking and wastewater account for roughly 2% of total West-wide electricity use, while an additional 1.2% is consumed by large-scale conveyance projects and 2.6% is consumed by agricultural pumping. The percent of electricity used for water services varies strongly by state with some as high as 34%, while other states expend less than 1%. Every county in the West uses some electricity for water services; however, there is a large disparity in use ranging from 10 MWh/yr to 5.8 TWh/yr. These results support long-term transmission planning in the Western U.S. by characterizing an important component of the electric load. © 2014 American Chemical Society.

Environmental Research Letters

Tidwell, Vincent C.; Roberts, Barry L.; Passell, Howard D.

Abstract not provided.

Tidwell, Vincent C.

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Tidwell, Vincent C.

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Tidwell, Vincent C.

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Tidwell, Vincent C.

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Tidwell, Vincent C.; Klise, Geoffrey T.

The purpose of this effort is to explore where the availability of water could be a limiting factor in the siting of new electric power generation. To support this analysis, water availability is mapped at the county level for the conterminous United States (3109 counties). Five water sources are individually considered, including unappropriated surface water, unappropriated groundwater, appropriated water (western U.S. only), municipal wastewater and brackish groundwater. Also mapped is projected growth in non-thermoelectric consumptive water demand to 2035. Finally, the water availability metrics are accompanied by estimated costs associated with utilizing that particular supply of water. Ultimately these data sets are being developed for use in the National Renewable Energy Laboratories' (NREL) Regional Energy Deployment System (ReEDS) model, designed to investigate the likely deployment of new energy installations in the U.S., subject to a number of constraints, particularly water.

Tidwell, Vincent C.

Abstract not provided.

Tidwell, Vincent C.; Backus, George A.; Naugle, Asmeret B.; Villa, Daniel V.; Brown, Theresa J.; Brune, Nancy E.; Keller, Elizabeth J.; Hayden, Nancy K.

Abstract not provided.

Tidwell, Vincent C.; Roberts, Barry L.; Passell, Howard D.

Abstract not provided.

Roach, Jesse D.; Tidwell, Vincent C.; Hightower, Marion M.

Abstract not provided.

Tidwell, Vincent C.; Backus, George A.; Naugle, Asmeret B.; Villa, Daniel V.; Brown, Theresa J.; Brune, Nancy E.; Keller, Elizabeth J.; Hayden, Nancy K.

Abstract not provided.

Tidwell, Vincent C.

Abstract not provided.