Quantifying spatial and temporal discharge dynamics of an event in a first order stream, using distributed temperature sensing

Westhoff, Martijn; Bogaard, Thom; Savenije, H. H. G.

doi:10.5194/hess-15-1945-2011

Cited by 26 publications

(26 citation statements)

References 49 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Thus, the evaluation statistics compared favourably to those observed in previous studies using similar models (e.g. Westhoff et al, 2011). The model was biased towards slight overprediction (as indicated by percent bias), but in all cases this was < 2.0 %.…”

Section: Modelled Spatio-temporal Water Temperature Patternssupporting

confidence: 69%

“…Several studies have documented daytime cooling gradients (instantaneous decreases in downstream temperature) under forest canopies located downstream of open (no trees) land use, although the magnitude of reported cooling effects varied between studies (e.g. Brown et al, 1971;Rutherford et al, 1997;McGurck, 1989;Keith et al, 1998;Zwieniecki and Newton, 1999;Torgerson et al, 1999;Story et al, 2003;Westhoff et al, 2011). For example, McGurck (1989), Keith et al (1998) and Story et al (2003) observed gradients of between 4.0 and 9.2 • C km −1 .…”

mentioning

confidence: 99%

See 1 more Smart Citation

What causes cooling water temperature gradients in forested stream reaches?

Garner¹,

Malcolm²,

Sadler³

et al. 2014

Preprint

View full text Add to dashboard Cite

Previous studies have suggested that shading by riparian vegetation may reduce maximum water temperatures and provide refugia for temperature-sensitive aquatic organisms. Longitudinal cooling gradients have been observed during the daytime for stream reaches shaded by coniferous trees downstream of clear cuts or deciduous woodland downstream of open moorland. However, little is known about the energy exchange processes that drive such gradients, especially in semi-natural woodland contexts without confounding cool groundwater inflows. To address this gap, this study quantified and modelled variability in stream temperature and heat fluxes along an upland reach of the Girnock Burn (a tributary of the Aberdeenshire Dee, Scotland) where riparian land use transitions from open moorland to semi-natural, predominantly deciduous woodland. Observations were made along a 1050 m reach using a spatially distributed network of 10 water temperature data loggers, 3 automatic weather stations and 211 hemispherical photographs that were used to estimate incoming solar radiation. These data parameterised a high-resolution energy flux model incorporating flow routing, which predicted spatio-temporal variability in stream temperature. Variability in stream temperature was controlled largely by energy fluxes at the water-columnatmosphere interface. Net energy gains occurred along the reach, predominantly during daylight hours, and heat exchange across the bed-water-column interface accounted for < 1 % of the net energy budget. For periods when daytime net radiation gains were high (under clear skies), differences between water temperature observations increased in the streamwise direction; a maximum instantaneous difference of 2.5 • C was observed between the upstream reach boundary and 1050 m downstream. Furthermore, daily maximum water temperature at 1050 m downstream was ≤ 1 • C cooler than at the upstream reach boundary and lagged by > 1 h. Temperature gradients were not generated by cooling of stream water but rather by a combination of reduced rates of heating in the woodland reach and advection of cooler (overnight and early morning) water from the upstream moorland catchment. Longitudinal thermal gradients were indistinct at night and on days when net radiation gains were low (under overcast skies), thus when changes in net energy gains or losses did not vary significantly in space and time, and heat advected into the reach was reasonably consistent. The findings of the study and the modelling approach employed are useful tools for assessing optimal planting strategies for mitigating against ecologically damaging stream temperature maxima.

show abstract

Section: Modelled Spatio-temporal Water Temperature Patternssupporting

confidence: 69%

mentioning

confidence: 99%

What causes cooling water temperature gradients in forested stream reaches?

Garner¹,

Malcolm²,

Sadler³

et al. 2014

Preprint

View full text Add to dashboard Cite

show abstract

“…Brown et al, 1971;Rutherford et al, 1997;McGurck, 1989;Keith et al, 1998;Zwieniecki and Newton, 1999;Torgerson et al, 1999;Story et al, 2003;Westhoff et al, 2011). For example, McGurck (1989), Keith et al (1998) and Story et al (2003) observed gradients of between 4.0 and 9.2 • C km −1 .…”

Section: G Garner Et Al: What Causes Cooling Water Temperature Gradmentioning

confidence: 98%

What causes cooling water temperature gradients in a forested stream reach?

Garner

Malcolm

Sadler

et al. 2014

Hydrol. Earth Syst. Sci.

103

View full text Add to dashboard Cite

Abstract. Previous studies have suggested that shading by riparian vegetation may reduce maximum water temperatures and provide refugia for temperature-sensitive aquatic organisms. Longitudinal cooling gradients have been observed during the daytime for stream reaches shaded by coniferous trees downstream of clear cuts or deciduous woodland downstream of open moorland. However, little is known about the energy exchange processes that drive such gradients, especially in semi-natural woodland contexts without confounding cool groundwater inflows. To address this gap, this study quantified and modelled variability in stream temperature and heat fluxes along an upland reach of the Girnock Burn (a tributary of the Aberdeenshire Dee, Scotland) where riparian land use transitions from open moorland to semi-natural, predominantly deciduous woodland. Observations were made along a 1050 m reach using a spatially distributed network of 10 water temperature data loggers, 3 automatic weather stations and 211 hemispherical photographs that were used to estimate incoming solar radiation. These data parameterised a high-resolution energy flux model incorporating flow routing, which predicted spatio-temporal variability in stream temperature. Variability in stream temperature was controlled largely by energy fluxes at the water-columnatmosphere interface. Net energy gains occurred along the reach, predominantly during daylight hours, and heat exchange across the bed-water-column interface accounted for < 1 % of the net energy budget. For periods when daytime net radiation gains were high (under clear skies), differences between water temperature observations increased in the streamwise direction; a maximum instantaneous difference of 2.5 • C was observed between the upstream reach boundary and 1050 m downstream. Furthermore, daily maximum water temperature at 1050 m downstream was ≤ 1 • C cooler than at the upstream reach boundary and lagged by > 1 h. Temperature gradients were not generated by cooling of stream water but rather by a combination of reduced rates of heating in the woodland reach and advection of cooler (overnight and early morning) water from the upstream moorland catchment. Longitudinal thermal gradients were indistinct at night and on days when net radiation gains were low (under overcast skies), thus when changes in net energy gains or losses did not vary significantly in space and time, and heat advected into the reach was reasonably consistent. The findings of the study and the modelling approach employed are useful tools for assessing optimal planting strategies for mitigating against ecologically damaging stream temperature maxima.

show abstract

“…In rivers, temperature exerts an important control on physiochemical characteristics of water [15] and it is a driver of Water 2017, 9, 358 2 of 16 numerous biological processes, controlling the structure of ecological communities and habitat complexity [16,17]. Approaches for measuring stream water temperature cover a wide range of methods including temperature loggers and thermometers [18][19][20], fiber-optic distributed temperature sensing (FO-DTS) [21,22] and thermal infrared (TIR) cameras [23][24][25].…”

Section: Introductionmentioning

confidence: 99%

Exploring Streamwater Mixing Dynamics via Handheld Thermal Infrared Imagery

Antonelli

Klaus

Smettem

et al. 2017

Water

View full text Add to dashboard Cite

Abstract:Stream confluences are important hotspots of aquatic ecological processes. Water mixing dynamics at stream confluences influence physio-chemical characteristics of the stream as well as sediment mobilisation and pollutant dispersal. In this study, we investigated the potential for handheld thermal infrared (TIR) imagery to provide rapid information on stream water mixing dynamics at small scales. In-situ visualisation of water mixing patterns can help reduce analytical errors related to stream water sampling locations and improve our understanding of how confluences and tributaries influence aquatic ecological communities. We compared TIR-inferred stream temperature distributions with water electrical conductivity and temperature (measured with a submerged probe) data from cross-channel transects. We show that the use of a portable TIR camera can enhance the visualisation of mixing dynamics taking place at stream confluences, identify the location of the mixing front between two different water sources and the degree of mixing. Interpretation of handheld TIR observations also provided information on how stream morphology and discharge can influence mixing dynamics in small streams. Overall, this study shows that TIR imagery is a valuable support technique for eco-hydrological investigation at small stream confluences.

show abstract

Quantifying spatial and temporal discharge dynamics of an event in a first order stream, using distributed temperature sensing

Cited by 26 publications

References 49 publications

What causes cooling water temperature gradients in forested stream reaches?

What causes cooling water temperature gradients in forested stream reaches?

What causes cooling water temperature gradients in a forested stream reach?

Exploring Streamwater Mixing Dynamics via Handheld Thermal Infrared Imagery

Contact Info

Product

Resources

About