More Like this

1. Lithium and water: Hydrosocial impacts across the life cycle of energy storage

   https://doi.org/10.1002/wat2.1748  

   Blair, James_J A; Vineyard, Noel; Mulvaney, Dustin; Cantor, Alida; Sharbat, Ali; Berry, Kate; Bartholomew, Elizabeth; Ornelas, Ariana Firebaugh (July 2024, WIREs Water)

   Abstract As a key ingredient of batteries for electric vehicles (EVs), lithium plays a significant role in climate change mitigation, but lithium has considerable impacts on water and society across its life cycle. Upstream extraction methods—including open‐pit mining, brine evaporation, and novel direct lithium extraction (DLE)—and downstream processes present different impacts on both the quantity and quality of water resources, leading to water depletion and contamination. Regarding upstream extraction, it is critical for a comprehensive assessment of lithium's life cycle to include cumulative impacts related not only to freshwater, but also mineralized or saline groundwater, also known as brine. Legal frameworks have obscured social and ecological impacts by treating brine as a mineral rather than water in regulation of lithium extraction through brine evaporation. Analysis of cumulative impacts across the lifespan of lithium reveals not only water impacts in conventional open‐pit mining and brine evaporation, but also significant freshwater needs for DLE technologies, as well as burdens on fenceline communities related to wastewater in processing, chemical contaminants in battery manufacturing, water use for cooling in energy storage, and water quality hazards in recycling. Water analysis in lithium life cycle assessments (LCAs) tends to exclude brine and lack hydrosocial context on the environmental justice implications of water use by life cycle stage. New research directions might benefit from taking a more community‐engaged and cradle‐to‐cradle approach to lithium LCAs, including regionalized impact analysis of freshwater use in DLE, as well as wastewater pollution, cooling water, and recycling hazards from downstream processes. This article is categorized under:Human Water > Human WaterHuman Water > Water GovernanceHuman Water > Water as Imagined and RepresentedScience of Water > Water and Environmental Change 

   more » « less
2. Water throughout the green energy transition: Hydrosocial dimensions of coal, natural gas, and lithium

   https://doi.org/10.1002/wat2.1751  

   Cousins, Joshua J; Cantor, Alida; Turley, Bethani (July 2024, WIREs Water)

   Abstract Energy transitions are reshaping hydrosocial relations. How they will be reshaped, however, depends on location and water's material relationship to other resources and industrial activities embedded within energy transitions. To highlight this, we focus on three different resources—coal, natural gas, and lithium—to signal how the water–energy nexus will be reworked in a transition away from fossil fuels. We examine the water–coal nexus as an example of a resource relationship that is transitioningout, or that is being moved away from in the green energy transition. Natural gas represents the “bridge fuel” usedthroughthe transition. Lithium illustrates a resourceinsidethe green transition, as it is a fundamental material for green technologiesinthe transition to a low‐carbon future. Coal, natural gas, and lithium each have their own material impacts to water resources that stem from their industrial lifecycle and different implications for communities shaped by coal, natural gas, and lithium activities. To explore this, we review each of these resources' connection to water, their legal and regulatory dimensions, and their impact on communities and water justice. We argue that the energy transition is also a hydrosocial transition that will create uneven water‐related benefits and burdens. To maximize sustainability and equity, efforts to decarbonize energy systems must examine the localized, place‐based hydrosocial relations that differentially affect communities. This article is categorized under:Engineering Water > Planning WaterHuman Water > Water GovernanceHuman Water > Rights to Water 

   more » « less
3. The effects of household water insecurity on child health and well‐being

   https://doi.org/10.1002/wat2.1666  

   Rhue, Steven J.; Torrico, Giulia; Amuzie, Chioma; Collins, Shalean M.; Lemaitre, Andrea; Workman, Cassandra L.; Rosinger, Asher Y.; Pearson, Amber L.; Piperata, Barbara A.; Wutich, Amber; et al (June 2023, WIREs Water)

   Abstract We extend the conceptualization of the social and health burdens of household water insecurity on children beyond the traditional narrow lens of microbiological pathogens and diarrhea. The global burden of disease associated with water insecurity has traditionally focused on diarrheal disease as the most significant driver of infant and child mortality. However, there are many other pathways through which children experience adverse health and social consequences from inadequate or unsafe household water. We synthesize evidence of a broad range of health impacts, affecting children from infancy to late adolescence, across four domains: exposure to unsafe water; interruptions to growth and development through poor nutrition and hydration; negative social effects such as school absenteeism and interpersonal violence; and other non‐communicable health issues such as mental health, injuries, and reproductive health. The growing burden and urgency of these issues is implicated by forecasted increases in climate‐ and conflict‐induced water scarcity, human displacement, and environmental contamination in the decades ahead. This article is categorized under:Engineering Water > Water, Health, and SanitationHuman Water > Rights to Water 

   more » « less
4. Boom, bust, action! How communities can cope with boom‐bust cycles in unconventional oil and gas development

   https://doi.org/10.1111/ropr.12490  

   Arnold, Gwen; Klasic, Meghan; Schomburg, Madline; York, Abigail; Baum, Melissa; Cherin, Maia; Cliff, Sydney; Kavousi, Parisa; Miller, Alexandria Tillett; Shajari, Diana; et al (June 2022, Review of Policy Research)

   Abstract Scholarship on boom‐busts cycles in resource extraction often assumes that affected resource‐rich communities are at best reactive, at worst helpless, in the face of the large, exogenous shocks this cycle visits upon them. Researchers infrequently examine what communities themselves can do to improve their economic prospects and residents' quality of life amidst booms and busts. In this review paper, we identify and synthesize work scattered across disparate academic and gray literature—in planning, law, community economic development, rural sociology, economics, and political science, among others—to holistically assess what we know about how communities can use local policymaking to manage impacts of booms and busts associated with unconventional oil and gas drilling (UOGD), often called “fracking.” We highlight examples of communities tackling this task using vertical and horizontal governance strategies and distill expert recommendations for how communities can build boom‐bust resiliency generally and in key areas impacted by UOGD. 

   more » « less
5. Mapping the landscape of water and society research: Promising combinations of compatible and complementary disciplines

   https://doi.org/10.1002/wat2.1701  

   Muller, Marc F.; Rusca, Maria; Bertassello, Leonardo; Adams, Ellis; Allaire, Maura; Cabello Villarejo, Violeta; Levy, Morgan; Mukherjee, Jenia; Pokhrel, Yadu (March 2024, WIREs Water)

   Abstract Coupled human‐water systems (CHWS) are diverse and have been studied across a wide variety of disciplines. Integrating multiple disciplinary perspectives on CHWS provides a comprehensive and actionable understanding of these complex systems. While interdisciplinary integration has often remained elusive, specific combinations of disciplines might be comparably easier to integrate (compatible), and/or their combination might be particularly likely to uncover previously unobtainable insights (complementary). This paper systematically identifies such promising combinations by mapping disciplines along a common set of topical, philosophical, and methodological dimensions. It also identifies key challenges and lessons for multidisciplinary research teams seeking to integrate highly promising (complementary) but poorly compatible disciplines. Applied to eight disciplines that span the environmental physical sciences and the quantitative and qualitative social sciences, we found that promising combinations of disciplines identified by the typology broadly reproduce patterns of recent interdisciplinary collaborative research revealed by a bibliometric analysis. We also found that some disciplines are centrally located within the typology by being compatible and complementary to multiple other disciplines along distinct dimensions. This points to the potential for these disciplines to act as catalysts for wider interdisciplinary integration. This article is categorized under:Engineering Water > MethodsHuman Water > MethodsScience of Water > Methods 

   more » « less