Jordan Jenckes scite author profile

Recent investments in renewable energy infrastructure on a global scale have doubled that of new energy from nuclear power and fossil fuels (REN21, 2018), as the global energy focus is transitioning away from nonrenewable resources. This transition and the explosion of the electric vehicle industry has consequently led to an increased demand for lithium (Li) as one of the major components of batteries for electric vehicles with a projected compound annual growth rate of 18% until 2030 (Roskill, 2020). Lithium is primarily found in three main deposits: (a) pegmatites, (b) continental brines, and (c) clays (

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Relic Groundwater and Prolonged Drought Confound Interpretations of Water Sustainability and Lithium Extraction in Arid Lands

Moran

Boutt

McKnight

et al. 2022

Earth's Future

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Demand for lithium for batteries is growing rapidly with the global push to decarbonize energy systems. The Salar de Atacama, Chile holds ∼42% of the planet's reserves in the form of brine hosted in massive evaporite aquifers. The mining of these brines and associated freshwater use has raised concerns over the environmental responsibility of lithium extraction, yet large uncertainties remain regarding fundamental aspects of governing hydrological processes in these environments. This incomplete understanding has led to the perpetuation of misconceptions about what constitutes sustainable or renewable water use and therefore what justifies responsible allocation. We present an integrated hydrological assessment using tritium and stable oxygen, and hydrogen isotopes paired with remotely sensed and terrestrial hydroclimate data to define unique sources of water distinguished by residence time, physical characteristics, and connectivity to modern climate. Our results describe the impacts of prolonged drought on surface and groundwaters and demonstrate that nearly all inflow to the basin is composed of water recharged >65 years ago. Still, modern precipitation is critical to sustaining important wetlands around the salar. Recent large rain events have increased surface water and vegetation extents and terrestrial water storage while mining‐related water withdrawals have continued. As we show, poor conceptualizations of these complex hydrological systems have perpetuated the misallocation of water and the misattribution of impacts. These fundamental issues apply to arid regions globally. Our new framework for hydrological assessment in these basins moves beyond calculating gross inputs‐outputs at a steady state to include all compartmentalized stores that constitute “modern” budgets.

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Concentration‐Discharge Patterns Across the Gulf of Alaska Reveal Geomorphological and Glacierization Controls on Stream Water Solute Generation and Export

Jenckes

Ibarra

Munk

2021

Geophysical Research Letters

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High-latitude regions are warming at rates of two to three times the global average (IPCC, 2007). Precipitation regime changes associated with the increasing temperatures will result in increased precipitation, primarily in the form of autumn and winter rain (Beamer et al., 2017). Associated with these changes, global glacier volume will decline 29-41% by 2100 compared to 2006 accompanied by a projected 20% decline in global glacier runoff (Radić et al., 2014). Ice fields and glaciers cover 18% of the 420,230 km 2 Gulf of Alaska (GoA) region and supply 47% of the freshwater water runoff (Neal et al., 2010). Looking to the future it is predicted that Alaska will experience a 30% decline in runoff by the end of the 21st century (Bliss et al., 2014) accompanied by a forecasted decrease of glacier volume between 32 ± 11 and 58 ± 14% for RCP2.6 and RCP8.5, respectively (Huss & Hock, 2015). As such, the climate change predicted for the 21st century will significantly alter the amount of freshwater discharging to the GoA along with changes in precipitation regimes. Currently, glacial fed streams have increased discharge compared to nonglacial precipitation fed streams. This paradigm will shift as coastal glacier coverage declines into the 21st century. Today, glaciers act as a control on seasonal runoff variation within a catchment. Stream discharge within a glacierized basin varies little year to year and peak runoff is generally predictable. Precipitation fed streams, conversely, have higher interannual variations in discharge due to their susceptibility to interannual climate variability. For example, Fountain and Tangborn (1985) suggest that basins with glacial coverage around 36% have the lowest year-to-year variation in discharge. Streams with less than 10% glacier cover, however, show large year to year variability in stream flow when compared to streams within watersheds with greater percentages of glacier coverage (Fountain & Tangborn, 1985).

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Jordan Jenckes

Hydroclimate Drives Seasonal Riverine Export Across a Gradient of Glacierized High‐Latitude Coastal Catchments

Lithium Storage and Release From Lacustrine Sediments: Implications for Lithium Enrichment and Sustainability in Continental Brines

Relic Groundwater and Prolonged Drought Confound Interpretations of Water Sustainability and Lithium Extraction in Arid Lands

Concentration‐Discharge Patterns Across the Gulf of Alaska Reveal Geomorphological and Glacierization Controls on Stream Water Solute Generation and Export

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