Use of Radiocarbon Ages to Narrow Groundwater Recharge Estimates in the Southeastern Mojave Desert, USA

Estimating groundwater recharge in arid or semiarid regions can be a difficult and complex task, since it is dependent on a highly variable set of spatial and temporal hydrologic parameters and processes that are dependent on the local climate, the land surface properties, and subsurface characteris...

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Bibliographic Details
Published inHydrology Vol. 5; no. 3; p. 51
Main Authors Love, Adam, Zdon, Andy
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.09.2018
Subjects
Age
Aquifers
Arid regions
Bonanza Spring
Climate change
Deserts
Earth science
Environmental impact
Estimates
Estimation
Flow characteristics
forensics
Geology
Groundwater
Groundwater recharge
Hydrology
isotopes
Laboratories
Mojave Desert
Mojave Trails National Monument
Mountains
Perennial springs
Precipitation
Process parameters
Radiocarbon dating
Radiometric dating
Semi arid areas
Semiarid lands
Spring
Spring water
Studies
Surface properties
water resources
Water springs
Mojave Desert
California
United States > US
Colorado River
Death Valley
Nevada
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Summary:Estimating groundwater recharge in arid or semiarid regions can be a difficult and complex task, since it is dependent on a highly variable set of spatial and temporal hydrologic parameters and processes that are dependent on the local climate, the land surface properties, and subsurface characteristics. As a result, traditional methods for estimating the recharge can result in a wide range of derived values. This is evident in the southeastern Mojave Desert, where calculated recharge estimates by previous investigators that range over an order of magnitude (from ~2500 to ~37,000 acre feet per year) are reported. To narrow down this large span of recharge estimates to narrower and more plausible values, this study evaluates the previous recharge estimates in this region, to examine the sources of variability in the reported results and to constrain the recharge estimates based on the hydrologic conditions and the radiocarbon age-dating of spring flows—even without knowledge of the precise subsurface hydrology. The groundwater age and perennial flow characteristics of springs in this study could not be derived from waters sourced solely from local recharge. Therefore, the springs in this study require a significant groundwater contribution to their overall discharge. A previously described conceptual site model in the region established that Bonanza Spring is similarly hydrologically connected to the regional basin-fill aquifer, based on geologic and geochemical/isotopic analyses, and this conceptual site model for where perennial spring water is sourced should readily be extended to these other perennial springs in this region.
ISSN:2306-5338
2306-5338
DOI:10.3390/hydrology5030051