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- All Subjects: Water scarcity
- Creators: White, Dave
- Resource Type: Text
- Status: Published
Description
The Water-Energy Nexus (WEN) is a concept that recognizes the interdependence of water and energy systems. The Phoenix metropolitan region (PMA) in Arizona has significant and potentially vulnerable WEN interactions. Future projections indicate that the population will increase and, with it, energy needs, while changes in future water demand are more uncertain. Climate change will also likely cause a reduction in surface water supply sources. Under these constraints, the expansion of renewable energy technology has the potential to benefit both water and energy systems and increase environmental sustainability by meeting future energy demands while lowering water use and CO2 emissions. However, the WEN synergies generated by renewables have not yet been thoroughly quantified, nor have the related costs been studied and compared to alternative options.Quantifying WEN intercations using numerical models is key to assessing renewable energy synergy. Despite recent advances, WEN models are still in their infancy, and research is needed to improve their accuracy and identify their limitations. Here, I highlight three research needs. First, most modeling efforts have been conducted for large-scale domains (e.g., states), while smaller scales, like metropolitan regions, have received less attention. Second, impacts of adopting different temporal (e.g., monthly, annual) and spatial (network granularity) resolutions on simulation accuracy have not been quantified. Third, the importance of simulating feedbacks between water and energy components has not been analyzed.
This dissertation fills these major research gaps by focusing on long-term water allocations and energy dispatch in the metropolitan region of Phoenix. An energy model is developed using the Low Emissions Analysis Platform (LEAP) platform and is subsequently coupled with a water management model based on the Water Evaluation and Planning (WEAP) platform. Analyses are conducted to quantify (1) the value of adopting coupled models instead of single models that are externally coupled, and (2) the accuracy of simulations based on different temporal resolutions of supply and demand and spatial granularity of the water and energy networks. The WEAP-LEAP integrated model is then employed under future climate scenarios to quantify the potential of renewable energy technologies to develop synergies between the PMA's water and energy systems.
ContributorsMounir, Adil (Author) / Mascaro, Giuseppe (Thesis advisor) / White, Dave (Committee member) / Garcia, Margaret (Committee member) / Xu, Tianfang (Committee member) / Chester, Mikhail (Committee member) / Arizona State University (Publisher)
Created2022
Description
The worldwide supply of potable fresh water is ever decreasing. While 2.5% of Earth's water is fresh, only 1% is accessible. Of this water, the World Health Organization estimates that only one-third can be used to meet our daily needs while the other two-thirds are unusable due to contamination. As the world population continues to grow and climate change reduces water security, we must consider not only solutions, but evaluate the perceptions and reactions of individuals in order to successfully implement such solutions. To that end, the goal of this dissertation is to explore human attitudes, beliefs, and behaviors around water issues by conducting cross-cultural comparisons of (1) water risks and solutions, (2) wastewater knowledge and acceptance, and (3) motivators for willingness to use treated wastewater. Previous research in these domains has primarily focused on a single site or national context. While such research is valuable for establishing how and why cultural context matters, comparative studies are also needed to help link perceptions at local and global scales. Adopting an interdisciplinary approach grounded in anthropological methods and theory, I use interview data collected in a range of international sites as part of the Arizona State University's Global Ethnohydrology Study. With funding from National Science Foundation grants to the Decision Center for a Desert City (DCDC) and the Central Arizona-Phoenix Long-Term Ecological Research project (CAP LTER), this dissertation explores cross-cultural perceptions of water threats and management strategies, specifically wastewater reclamation and reuse, in order to make recommendations for policy makers and water managers.
ContributorsStotts, Rhian (Author) / Wutich, Amber (Thesis advisor) / BurnSilver, Shauna (Committee member) / Grossman, Gary (Committee member) / White, Dave (Committee member) / Arizona State University (Publisher)
Created2016