Your search keyword '"Gerenday, Sarah P."' showing total 3 results

1. Sulfur Hexafluoride and Potassium Bromide as Groundwater Tracers for Managed Aquifer Recharge.

Author

Gerenday SP, Clark JF, Hansen J, Fischer I, and Koreny J

Subjects

Bromides, Potassium Compounds, Prospective Studies, Sulfur Hexafluoride, Washington, Groundwater

Abstract

Sulfur hexafluoride (SF 6 ) is an established tracer for use in managed aquifer recharge projects. SF 6 exsolves from groundwater when it encounters trapped air according to Henry's law. This results in its retardation relative to groundwater flow, which can help determine porous media saturation and flow dynamics. SF 6 and the conservative, nonpartitioning tracer, bromide (Br - added as KBr), were introduced to recharge water infiltrated into stacked glacial aquifers in Thurston County, Washington, providing the opportunity to observe SF 6 partitioning. Br - , which is assumed to travel at the same velocity as the groundwater, precedes SF 6 at most monitoring wells (MWs). Average groundwater velocity in the unconfined aquifer in the study area ranges from 3.9 to 40 m/d, except in the southwestern corner where it is slower. SF 6 in the shallow aquifer exhibits an average retardation factor of 2.5 ± 3.8, suggesting an air-to-water ratio on the order of 10 -3 to 10 -2 in the pore space. Notable differences in tracer arrival times at adjacent wells indicate very heterogeneous conductivity. One MW exhibits double peaks in concentrations of both tracers with different degrees of retardation for the first and second peaks. This suggests multiple flowpaths to the well with variable saturation. The confining layer between the upper two aquifers appears to allow intermittent connection between aquifers but serves as an aquitard in most areas. This study demonstrates the utility of SF 6 partitioning for evaluating hydrologic conditions at prospective recharge sites., (© 2020, National Ground Water Association.)

Published

2020

2. Investigation of conditions relevant to the use of reclaimed water for managed aquifer recharge in two aquifer systems in the Western United States

Author

Gerenday, Sarah Paschal

Subjects

Hydrologic sciences, Water resources management, Geochemistry, groundwater, Managed aquifer recharge, reclaimed water, recycled water, SGMA

Abstract

Managed aquifer recharge (MAR) is an increasingly popular strategy for maintaining a sustainable water supply. Reclaimed water (sometimes referred to as recycled water) can be used as a supply of recharge water, providing environmental benefits, while natural processes improve the quality of this water. Planning and implementing such projects requires understanding of the flow patterns and geochemistry of the target aquifers in addition to health and logistical constraints. This dissertation contains three studies of conditions for various phases of reclaimed water MAR projects in two different hydrogeologic and legal settings. Chapter 2 is a suitability analysis of land for reclaimed water MAR in the California's Central Valley in the context of the Sustainable Groundwater Management Act, which requires Groundwater Sustainability Agencies (GSA) to develop Groundwater Sustainability Plans (GSP). Land is scored in terms of the suitability of its soil and proximity to potential sources of reclaimed water. Inherently unsuitable land is excluded based on land cover and mandatory buffers for domestic wells. Backwards particle tracking is used to identify areas where recharged water would not meet minimum residence time criteria specified in California's water code, and these areas are also excluded. Land deemed suitable for reclaimed water MAR is compared to the land needed by GSAs in critically overdrafted basins to fulfil the recharge goals laid out in their GSPs. Potential recycled water availability is determined based on the discharge volumes of local water recycling and wastewater treatment plants. Under existing conditions, only 2 out of 29 GSAs have enough potentially suitable land to meet their recharge goals using sufficiently high-quality reclaimed water as a source, and none have enough high quality water, though the numbers increase if existing treatment plants can be upgraded.Chapter 3 details a tracer study and monitoring project conducted at the LOTT Clean Water Alliance's Hawks Prairie Reclaimed Water Ponds and Recharge Basins site in Thurston County, Washington. The study employs sulfur hexafluoride (SF6) and bromide (Br-) as added tracers to identify flow paths and determine residence times for reclaimed water recharged from the basins. As a low-solubility gas, the SF6 exhibits an exsolution – dissolution behavior according to Henry's law in the presence of air trapped within the soil and aquifer media, resulting in its retardation relative to the Br-. This retardation is used to calculate an air to water ratio of 10^-3 to 10^-2 along the flow paths of the recharge water. It is also demonstrated that the water follows several non-linear preferential pathways and that water can travel between the two uppermost aquifers in certain locations.Chapter 4 examines the broader geochemistry of groundwater in the upper and intermediate aquifer units of Thurston County, Washington, where the Hawks Prairie MAR site from chapter 3 is located. Groundwater is determined to be composed of concentrated meteoric water with additional solutes from mineral weathering. More evolved waters contain lower levels of oxygen with higher iron, manganese, and phosphorus contents. Groundwater may also be contaminated by seawater intrusion or septic effluent, resulting in elevated concentrations of chloride and, in the case of septic contamination, nitrate. This demonstrates the importance of familiarity with the local inputs that control groundwater quality in order to ensure compatibility with MAR.Together, these studies demonstrate the major phases and considerations of reclaimed water MAR projects. To be successful, projects must consider appropriate siting, transport conditions and geochemistry. With sufficient planning and attention to these details, reclaimed water MAR can be a valuable tool for ensuring water sustainability.

Published

2022

3. Recycled water could recharge aquifers in the Central Valley.

Author

Gerenday, Sarah P., Perrone, Debra, Clark, Jordan F., and Ulibarri, Nicola

Subjects

*AQUIFERS, *GROUNDWATER, *WATER use, *ARTIFICIAL groundwater recharge

Abstract

Drawing out too much groundwater, or overdrafting, is a serious problem in California. As a result, groundwater sustainability agencies are considering using recycled municipal wastewater to recharge aquifers. In our study, we employ suitability mapping and the models C2VSimFG and Ichnos to identify appropriate areas for managing aquifer recharge with recycled water in California's Central Valley. The factors that influence suitability include soil properties, proximity to recycled water sources, and the residence time, or amount of time that recharged water spends underground. There are many suitable areas in the Central Valley that are immediately adjacent to water recycling facilities. However, adequate supply is an issue in most locations. Roughly half of the groundwater sustainability agencies in critically overdrafted basins of the Central Valley have enough potentially suitable locations to meet their recharge goals, but not all of them have access to enough recycled water. The methods demonstrated here can serve as tools for agencies considering using recycled water for aquifer recharge. [ABSTRACT FROM AUTHOR]

Published

2023