Buffered, lagged, or cooled? Disentangling hyporheic influences on temperature cycles in stream channels

Arrigoni, Alicia S.; Poole, Geoffrey C.; Mertes, Leal A. K.; O'Daniel, S. J.; Woessner, William; Thomas, Steven A.

doi:10.1029/2007wr006480

Cited by 181 publications

(183 citation statements)

References 68 publications

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“…The HZ is a unique ecotone that supports a variety of hydrological, ecological and biogeochemical processes essential to river ecosystem function (Gibert et al, 1990;Boulton et al, 2010). By regulating the transfer of heat and mass across the sediment-water interface, the HZs play a critical role in temperature buffering (Arrigoni et al, 2008) and biogeochemical cycling (Mulholland and Webster, 2010). They are also permanent habitats for many microbes and invertebrates (Brunke and Gonser, 1999), provide refugia for surface invertebrates or fish (Dole-Olivier, 2011; Kawanishi et al, 2013), and are used by some fish for spawning (Geist et al, 2002).…”

mentioning

confidence: 99%

Variation in reach-scale hydraulic conductivity of streambeds

Stewardson

Datry²,

Lamouroux³

et al. 2016

Geomorphology

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Streambed hydraulic conductivity is an important control on flow within the hyporheic zone, affecting hydrological, ecological, and biogeochemical processes essential to river ecosystem function. Despite many published field measurements, few empirical studies examine the drivers of spatial and temporal variations in streambed hydraulic conductivity. Reach-averaged hydraulic conductivity estimated for 119 surveys in 83 stream reaches across continental France, even of coarse bed streams, are shown to be characteristic of sand and finer sediments. This supports a model where processes leading to the accumulation of finer sediments within streambeds largely control hydraulic conductivity rather than the size of the coarse bed sediment fraction. After describing a conceptual model of relevant processes, we fit an empirical model relating hydraulic conductivity to candidate geomorphic and hydraulic drivers. The fitted model explains 72% of the deviance in hydraulic conductivity (and 30% using an external cross-validation). Reach hydraulic conductivity increases with the amplitude of bedforms within the reach, the bankfull channel width-depth ratio, stream power and upstream catchment erodibility but reduces with time since the last streambed disturbance. The correlation between hydraulic conductivity and time since a streambed mobilisation event is likely a consequence of clogging processes. Streams with a predominantly suspended load and less frequent streambed disturbances are expected to have a lower streambed hydraulic conductivity and reduced hyporheic fluxes. This study suggests a close link between streambed sediment transport dynamics and connectivity between surface water and the hyporheic zone.

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mentioning

confidence: 99%

Variation in reach-scale hydraulic conductivity of streambeds

Stewardson

Datry²,

Lamouroux³

et al. 2016

Geomorphology

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“…The daily mean hyporheic water temperature is equal to the mean in-stream water temperature in all cases as observed in the field studies of Arrigoni et al [2008]. The signal of the upwelling water temperature is characterized by a time lag, the lagged effect in Arrigoni et al [2008], and an attenuation defined as the buffered effect in Arrigoni et al [2008]. These effects relate directly with the dimension of the stream and consequently with the hyporheic residence time.…”

Section: Comparison With Field Measurementsmentioning

confidence: 98%

“…Figure 9 shows the in-stream temperature and the hyporheic temperature averaged over the upwelling areas for both small steep-gradient, medium moderate-gradient, and large low-gradient streams (Test 1, Test 10, and Test 18 of Table 2, respectively). The daily mean hyporheic water temperature is equal to the mean in-stream water temperature in all cases as observed in the field studies of Arrigoni et al [2008]. The signal of the upwelling water temperature is characterized by a time lag, the lagged effect in Arrigoni et al [2008], and an attenuation defined as the buffered effect in Arrigoni et al [2008].…”

Section: Comparison With Field Measurementsmentioning

confidence: 99%

“…Consequently, we hypothesize a complex three-dimensional hyporheic temperature distribution in gravel bed rivers with pool-riffle morphology, which reflects the flow pattern. To test this hypothesis, we develop a novel threedimensional semianalytical process-based model, which accounts for advection, diffusion, and conduction, for predicting the thermal regime within the hyporheic zone [Anderson, 2005;Hohen and Cirpka, 2006;Cardenas and Wilson, 2007;Arrigoni et al, 2008]. We focus our investigation on pool-riffle bed form because of its ubiquity and ecological importance Buffington and Tonina, 2009).…”

Section: Introductionmentioning

confidence: 99%

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Effects of stream morphodynamics on hyporheic zone thermal regime

Marzadri

Tonina

Bellin

2013

Water Resources Research

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[1] We develop a heat-transport model to study the impact of streambed morphology on temperature distribution within the hyporheic zone of gravel bed rivers. The heat transport model, which includes conduction, diffusion, and advection, is solved by a Lagrangian approach, neglecting transverse dispersion and considering stream water temperature as boundary condition at the streambed. First, we show that the model accurately reproduces the temperature distribution measured within the hyporheic zone of a reach of the Bear Valley Creek, Idaho (USA). Our model reveals spatially complex patterns of hyporheic water temperatures that vary with time within the hyporheic zone and at the streambed surface. The analysis shows that temperature distributions are primarily related to the hyporheic residence time and consequently to the bed morphology and in-stream flow discharge. Results show that the hyporheic temperature amplitudes are smaller than the surface water temperature and they decrease with stream size, leading hyporheic zones of large streams to be independent from in-stream daily temperature fluctuations.Citation: Marzadri, A., D. Tonina, and A. Bellin (2013), Effects of stream morphodynamics on hyporheic zone thermal regime, Water Resour.

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“…These patterns of connectivity control water mixing from various sources, each of which has its own distinct characteristics, including turbidity (Mertes 1997), temperature (Arrigoni et al 2008), and composition of dissolved constituents (Dent et al 2001). Any of such characteristics can influence the ecological processes occurring within a parcel of water on a floodplain.…”

Section: A Spatially Explicit Hydrologic Templatementioning

confidence: 99%