2013
DOI: 10.1016/j.jhydrol.2013.02.030
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Groundwater flow and mixing in a wetland–stream system: Field study and numerical modeling

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Cited by 34 publications
(45 citation statements)
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References 29 publications
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“…8) are similar to the findings of Gonzales et al (2009) for a lowland stream, and could indicate the occurrence of a component which is not accounted for by either of the two hydrograph separation methods (Wels et al, 1991;Hooper and Shoemaker, 1986). According to Karan et al (2013), a shallow relatively young groundwater component was discharging to the stream at station 4, supporting the idea that the stream-flow components could be divided into a deep groundwater component discharging right beneath the stream channel, a shallow component and a surface/event water component. However, there was no distinct difference between the average EC and δ 2 H of the shallow soil/groundwater and the deep groundwater.…”
Section: Temporal Dynamics and Catchment-scale Differences In Runoff supporting
confidence: 70%
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“…8) are similar to the findings of Gonzales et al (2009) for a lowland stream, and could indicate the occurrence of a component which is not accounted for by either of the two hydrograph separation methods (Wels et al, 1991;Hooper and Shoemaker, 1986). According to Karan et al (2013), a shallow relatively young groundwater component was discharging to the stream at station 4, supporting the idea that the stream-flow components could be divided into a deep groundwater component discharging right beneath the stream channel, a shallow component and a surface/event water component. However, there was no distinct difference between the average EC and δ 2 H of the shallow soil/groundwater and the deep groundwater.…”
Section: Temporal Dynamics and Catchment-scale Differences In Runoff supporting
confidence: 70%
“…As previous studies (Jensen and Engesgaard, 2011;Karan et al, 2013) in the same area only detected moderate seasonal changes in streambed temperatures, the steady-state conditions were assumed to be valid for the study period in June. For each VTP, T s was given as the temperature measured by the uppermost sensor, and the constant groundwater temperature of 8 • C (T g ) was assumed at a depth of 5 m (L).…”
Section: Methodsmentioning
confidence: 99%
“…The range in daily mean temperatures in the lower data logger at the four other loggers is more damped. Further, the inter‐quartile range in daily mean temperatures of these lower loggers is clustered closer to 8 °C equivalent to mean surface‐near groundwater temperature in Denmark and within the study catchment (Jensen & Engesgaard, ; Karan et al, ; Kidmose et al, ). In contrast, daily mean temperatures at the lower data loggers at the remaining sites show greater variation and thus a larger inter‐quartile range closer to that of their corresponding upper data logger.…”
Section: Resultsmentioning
confidence: 87%
“…Because the location of the measurements is close to the shore, density was assumed to be dominated by discharging fresh groundwater. Groundwater temperature was expected to oscillate between 8 °C and 11.5 °C based on the thermal stability of groundwater reported in previous studies (Arriaga and Leap, ) as well as in Denmark (Karan et al ., ). The difference in deeper groundwater temperature between October and May–August was attributed to the heating of the system at the end of the summer season.…”
Section: Methodsmentioning
confidence: 99%