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Passive pore water sampling provides evidence of suppression of hyporheic exchange and ntrate transformation in a groundwater-fed river

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Publication date2013
Number of pages8
<mark>Original language</mark>English
Event13th International Conference on Environmental Science and Technology - Athens, Greece
Duration: 5/09/20137/09/2013

Conference

Conference13th International Conference on Environmental Science and Technology
Country/TerritoryGreece
CityAthens
Period5/09/137/09/13

Abstract

In recent years, the potential of riverbed hyporheic sediments to attenuate nitrate from polluted groundwater has received much attention. However, transformation of reactive nitrate along upwelling flow paths is dependent on redox conditions and the availability of electron donors; these biogeochemical conditions are in turn strongly dependent on hydro-morphologic drivers including riverbed structure and water flux. We worked on a 50m stretch of the River Leith, Cumbria, UK, which is dominated by upwelling nitrate-rich groundwater. Previous investigations of hyporheic connectivity and pore water chemistry in our sub-reach suggest strong groundwater upwelling might suppress the hyporheic zone, possibly restraining its ability to attenuate nitrate in the upwelling groundwater. However, this hypothesis could not be verified previously due to the difficulty of measuring pore water chemistry at depths in the riverbed <10cm. The goal of this paper is to test whether nitrate attenuation is occurring in riverbed sediments characterised by strong vertical water fluxes. We utilised diffusive equilibrium in thin-films (DET) samplers to capture high resolution (cm-scale) vertical concentration profiles of nitrate in the upper 15cm of the riverbed sediments. The vertical concentration profiles obtained from DET probes indicate considerable cm-scale variability in concentrations. However, the overall trend suggests the absence of substantial net chemical transformations and surface-subsurface water mixing in the shallow sediments of our sub-reach.