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06.01.2022 | Paper

Estimating groundwater mean transit time from SF₆ in stream water: field example and planning metrics for a reach mass-balance approach

verfasst von: Craig R. Jensen, David P. Genereux, Troy E. Gilmore, D. Kip Solomon, Aaron R. Mittelstet, C. Eric Humphrey, Markus R. MacNamara, Caner Zeyrek, Vitaly A. Zlotnik

Erschienen in: Hydrogeology Journal | Ausgabe 2/2022

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Abstract

Stream reach mass-balance can be used to estimate groundwater age at scales larger than individual wells. Atmospherically derived SF₆ was used as an age-dating tracer in reach mass-balance analysis of six stream reaches in Nebraska, USA. The goal was to estimate the flow-weighted mean SF₆ concentration in the groundwater discharge to each reach (C_gw) and the groundwater mean transit time (MTT) based on C_gw. The C_gw in one reach (1.48 fmol/kg) was consistent with a MTT of 27 years. High uncertainty in C_gw prevented plausible MTT estimates in the other reaches. Monte Carlo analyses indicated that low rates of groundwater inflow to the stream reaches (Q_gw) led to high uncertainty in C_gw. This issue can affect the success of any reach mass-balance analysis, for age dating tracers or other solutes. To improve the likelihood of success in future applications of reach mass-balance, two new planning metrics are proposed for use, separately or together: the ratio of groundwater recharge rate (R) to stream density (D) within a watershed, and the long-term average Q_gw/Q_d in a stream reach (where Q_d is stream discharge at the downstream end of the reach). In comparison to the Nebraska study site (R/D = 107 m²/year), more accurate estimation of C_gw was achieved in a previous SF₆ study in North Carolina (USA) with greater R/D (231 m²/year). Larger Q_gw/Q_d is associated with more accurate outcomes in reach mass-balance, and long-term average Q_gw/Q_d in stream reaches may be estimated by GIS analysis of watershed areas and/or stream lengths.

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Titel: Estimating groundwater mean transit time from SF6 in stream water: field example and planning metrics for a reach mass-balance approach
verfasst von: Craig R. Jensen
David P. Genereux
Troy E. Gilmore
D. Kip Solomon
Aaron R. Mittelstet
C. Eric Humphrey
Markus R. MacNamara
Caner Zeyrek
Vitaly A. Zlotnik
Publikationsdatum: 06.01.2022
Verlag: Springer Berlin Heidelberg
Erschienen in: Hydrogeology Journal / Ausgabe 2/2022
Print ISSN: 1431-2174
Elektronische ISSN: 1435-0157
DOI: https://doi.org/10.1007/s10040-021-02435-8

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