Identifying the Origin and Evolution of Groundwater in the Salt River Valley and Applications for Better Water Well Design: A Stable Isotopic Approach
abstract: Stable isotopes were measured in the groundwaters of the Salt River Valley basin in central Arizona to explore the utility of stable isotopes for sourcing recharge waters and engineering better well designs. Delta values for the sampled groundwaters range from -7.6‰ to -10‰ in 18O and -60‰...
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ndltd-asu.edu-item-189312018-06-22T03:04:28Z Identifying the Origin and Evolution of Groundwater in the Salt River Valley and Applications for Better Water Well Design: A Stable Isotopic Approach abstract: Stable isotopes were measured in the groundwaters of the Salt River Valley basin in central Arizona to explore the utility of stable isotopes for sourcing recharge waters and engineering better well designs. Delta values for the sampled groundwaters range from -7.6‰ to -10‰ in 18O and -60‰ to -91‰ in D and display displacements off the global meteoric water line indicative of surficial evaporation during river transport into the area. Groundwater in the basin is all derived from top-down river recharge; there is no evidence of ancient playa waters even in the playa deposits. The Salt and Verde Rivers are the dominant source of groundwater for the East Salt River valley- the Agua Fria River also contributes significantly to the West Salt River Valley. Groundwater isotopic compositions are generally more depleted in 18O and D with depth, indicating past recharge in cooler climates, and vary within subsurface aquifer layers as sampled during well drilling. When isotopic data were evaluated together with geologic and chemical analyses and compared with data from the final well production water it was often possible to identify: 1) which horizons are the primary producers of groundwater flow and how that might change with time, 2) the chemical exchange of cations and anions via water-rock interaction during top-down mixing of recharge water with older waters, 3) how much well production might be lost if arsenic-contributing horizons were sealed off, and 4) the extent to which replacement wells tap different subsurface water sources. In addition to identifying sources of recharge, stable isotopes offer a new and powerful approach for engineering better and more productive water wells. Bond, Angela Nicole (Author) Knauth, Paul (Advisor) Hartnett, Hilairy (Committee Member) Shock, Everett (Committee Member) Arizona State University (Publisher) Groundwater Salt River Valley Isotopes eng 119 pages M.S. Geological Sciences 2010 http://hdl.handle.net/2286/R.I.18931 http://rightsstatements.org/vocab/InC/1.0/ All Rights Reserved 2010 |
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Groundwater Salt River Valley Isotopes |
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Groundwater Salt River Valley Isotopes Identifying the Origin and Evolution of Groundwater in the Salt River Valley and Applications for Better Water Well Design: A Stable Isotopic Approach |
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abstract: Stable isotopes were measured in the groundwaters of the Salt River Valley basin in central Arizona to explore the utility of stable isotopes for sourcing recharge waters and engineering better well designs. Delta values for the sampled groundwaters range from -7.6‰ to -10‰ in 18O and -60‰ to -91‰ in D and display displacements off the global meteoric water line indicative of surficial evaporation during river transport into the area. Groundwater in the basin is all derived from top-down river recharge; there is no evidence of ancient playa waters even in the playa deposits. The Salt and Verde Rivers are the dominant source of groundwater for the East Salt River valley- the Agua Fria River also contributes significantly to the West Salt River Valley. Groundwater isotopic compositions are generally more depleted in 18O and D with depth, indicating past recharge in cooler climates, and vary within subsurface aquifer layers as sampled during well drilling. When isotopic data were evaluated together with geologic and chemical analyses and compared with data from the final well production water it was often possible to identify: 1) which horizons are the primary producers of groundwater flow and how that might change with time, 2) the chemical exchange of cations and anions via water-rock interaction during top-down mixing of recharge water with older waters, 3) how much well production might be lost if arsenic-contributing horizons were sealed off, and 4) the extent to which replacement wells tap different subsurface water sources. In addition to identifying sources of recharge, stable isotopes offer a new and powerful approach for engineering better and more productive water wells. === M.S. Geological Sciences 2010 |
author2 |
Bond, Angela Nicole (Author) |
author_facet |
Bond, Angela Nicole (Author) |
title |
Identifying the Origin and Evolution of Groundwater in the Salt River Valley and Applications for Better Water Well Design: A Stable Isotopic Approach |
title_short |
Identifying the Origin and Evolution of Groundwater in the Salt River Valley and Applications for Better Water Well Design: A Stable Isotopic Approach |
title_full |
Identifying the Origin and Evolution of Groundwater in the Salt River Valley and Applications for Better Water Well Design: A Stable Isotopic Approach |
title_fullStr |
Identifying the Origin and Evolution of Groundwater in the Salt River Valley and Applications for Better Water Well Design: A Stable Isotopic Approach |
title_full_unstemmed |
Identifying the Origin and Evolution of Groundwater in the Salt River Valley and Applications for Better Water Well Design: A Stable Isotopic Approach |
title_sort |
identifying the origin and evolution of groundwater in the salt river valley and applications for better water well design: a stable isotopic approach |
publishDate |
2010 |
url |
http://hdl.handle.net/2286/R.I.18931 |
_version_ |
1718700224209223680 |