Time variability and uncertainty in the fraction of young water in a small headwater catchment

Stockinger, Michael; Bogena, Heye; Lücke, Andreas; Stumpp, Christine; Vereecken, Harry

doi:10.5194/hess-23-4333-2019

Cited by 27 publications

(28 citation statements)

References 48 publications

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“…This, in turn, can affect the transport of Dissolved Organic Carbon (DOC) through the vadose zone (e.g., [58]). Clearly, the transport of DOC is closely linked to its transit time as it reflects the potential of soils to buffer DOC [59,60]. The results of this study suggested that DOC export at the catchment scale will also be influenced by the direct effect of deforestation on preferential flow processes.…”

Section: Implications Of the Presented Resultsmentioning

confidence: 85%

Effects of Deforestation on Water Flow in the Vadose Zone

Wiekenkamp

Huisman

Bogena

et al. 2019

Water

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The effects of land use change on the occurrence and frequency of preferential flow (fast water flow through a small fraction of the pore space) and piston flow (slower water flow through a large fraction of the pore space) are still not fully understood. In this study, we used a five year high resolution soil moisture monitoring dataset in combination with a response time analysis to identify factors that control preferential and piston flow before and after partial deforestation in a small headwater catchment. The sensor response times at 5, 20 and 50 cm depths were classified into one of four classes: (1) non-sequential preferential flow, (2) velocity based preferential flow, (3) sequential (piston) flow, and (4) no response. The results of this analysis showed that partial deforestation increased sequential flow occurrence and decreased the occurrence of no flow in the deforested area. Similar precipitation conditions (total precipitation) after deforestation caused more sequential flow in the deforested area, which was attributed to higher antecedent moisture conditions and the lack of interception. At the same time, an increase in preferential flow occurrence was also observed for events with identical total precipitation. However, as the events in the treatment period (after deforestation) generally had lower total, maximum, and mean precipitation, this effect was not observed in the overall occurrence of preferential flow. The results of this analysis demonstrate that the combination of a sensor response time analysis and a soil moisture dataset that includes pre-and post-deforestation conditions can offer new insights in preferential and sequential flow conditions after land use change.

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Section: Implications Of the Presented Resultsmentioning

confidence: 85%

Effects of Deforestation on Water Flow in the Vadose Zone

Wiekenkamp

Huisman

Bogena

et al. 2019

Water

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“…Both KGE' and the characteristics of the criterion response surface were utilized to search for the optimum model parameters (Dwivedi et al, 2021). The following ranges of model parameters were considered: Mean transit time: 1 to 50 years when using tritium, which serves as a groundwater age tracer at a time scale of 1 to 50 years (Suckow, 2014;Aggarwal, 2013;Gleeson et al, 2015). Shape parameter (α) for the Gamma TTD: 0.1 to 15 (Stewart et al (2017).…”

Section: Optimization Of Model Parameters Using the Downhill Simplex Methods In Conjunction With A Performance Criterionmentioning

confidence: 99%

“…With respect to δ 18 O, method-and period-based * estimates were coupled to previously established TTD parameters (Dwivedi et al, 2021), and multi-year average values of * were used to compare between different methods (Stockinger et al (2019); Gallart et al (2020a). The * was estimated as a function of period using * estimates obtained from application of each of the three methods.…”

Section: Estimation Of Fyw and Tyw Using Various Tracersmentioning

confidence: 99%

“…Stable water isotopes are generally considered applicable to determine groundwater ages up to 5 years (DeWalle et al, 1997;Dwivedi et al, 2021) and are therefore appropriate for subsurface storages with faster flow (Stewart et al, 2010). In contrast, 3 H is generally considered applicable up to a period of 50 years (Suckow, 2014;Aggarwal, 2013) and is thus appropriate for estimating "hidden" or deep groundwater contributions to streamflow (Stewart et al, 2012). The current study that uses both tracers can separate the contributions of both quick and slow groundwater flow to streamflow in a headwater mountain catchment.…”

Section: H-based Ttd Type and Mtt Estimatesmentioning

confidence: 99%

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Tandem use of transit time distribution and fraction of young water reveals the dynamic flow paths supporting streamflow at a mountain headwater catchment

Dwivedi

Eastoe

Knowles

et al. 2021

Preprint

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Abstract. Current understanding of the dynamic flow paths and subsurface water storages that support streamflow in mountain catchments is inhibited by the lack of long-term hydrologic data and the frequent use of single age tracers that are not applicable to older groundwater reservoirs. To address this, the current study used both multiple metrics and tracers to characterize the transient nature of flow paths with respect to change in catchment storage at Marshall Gulch, a sub-humid headwater catchment in the Santa Catalina Mountains, Arizona, USA. The fraction of streamflow that was untraceable using stable water isotope tracers was also estimated. A Gamma-type transit time distribution (TTD) was appropriate for deep groundwater analysis, but there were errors in the TTD shape parameters arising from the short record length of 3H in deep groundwater and stream water, and inconsistent seasonal cyclicity of the precipitation 3H time series data. Overall, the mean transit time calculated from 3H data was more than two decades greater than the mean transit time based on δ18O at the same site. The fraction of young water (Fyw) in shallow groundwater was estimated from δ18O time series data using weighted wavelet transform (WWT), iteratively re-weighted least squares (IRLS), and TTD-based methods. Estimates of Fyw depended on sampling frequency, the method of estimation, bedrock geology, hydroclimate, and factors affecting streamflow generation processes. The coupled use of Fyw and discharge sensitivity indicated highly dynamic flow paths that reorganized with changes in shallow catchment storage. The utility of 3H to determining Fyw in deeper groundwater was limited by data quality. Given that Fyw, discharge sensitivity, and mean transit time all yield unique information, this work demonstrates how co-application of multiple methods can yield a more complete understanding of the transient flow paths and observable storage volumes that contribute to streamflow in mountain headwater catchments.

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“…The separation of precipitation into drainage, groundwater recharge and evapotranspiration on its way through a catchment and along the various water flow paths can be strongly influenced by deforestation-induced changes. One method of studying these changes is to use the stable isotopes of water (δ 18 O and δ 2 H) as tracers of water flow paths (Stockinger et al, 2019). In previous decades, several studies analysed the response of water balance components to deforestation, but studies using longterm stable isotope data to analyse the effects on the travel time of runoff components, for example, subsurface water flow, are still lacking.…”

Section: Introductionmentioning

confidence: 99%

Long‐term stable water isotope and runoff data for the investigation of deforestation effects on the hydrological system of the Wüstebach catchment, Germany

Bogena

Stockinger

Lücke

2020

Hydrological Processes

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The Wüstebach catchment belongs to the German TERENO (Terrestrial Environmental Observatories) network and was partially deforested (21%) by the Eifel National Park in 2013. In this data paper, we provide 11-year precipitation and stream water isotope data and the corresponding runoff discharge rates recorded in the Wüstebach catchment (from 2009 to 2019). In addition, we provide an overview of available datasets and access information for environmental data of the Wüstebach catchment that are discoverable with associated metadata at the Web-based TERENO data portal. We anticipate that this comprehensive data set will give new insights in how deforestation influences the hydrological system, for exampole, in terms of transit time distribution, fraction of young water and water flow paths at the catchment scale.

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Time variability and uncertainty in the fraction of young water in a small headwater catchment

Cited by 27 publications

References 48 publications

Effects of Deforestation on Water Flow in the Vadose Zone

Effects of Deforestation on Water Flow in the Vadose Zone

Tandem use of transit time distribution and fraction of young water reveals the dynamic flow paths supporting streamflow at a mountain headwater catchment

Long‐term stable water isotope and runoff data for the investigation of deforestation effects on the hydrological system of the Wüstebach catchment, Germany

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