Looking to the Skies: Realising the Combined Potential of Drones and Thermal Infrared Imagery to Advance Hydrological Process Understanding in Headwaters

Dugdale, Stephen J.; Klaus, Julian; Hannah, David M.

doi:10.1029/2021wr031168

Cited by 19 publications

(14 citation statements)

References 78 publications

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“…To achieve this, the ecohydrological community needs to leverage new measurement approaches, generate new data sets, and rely on novel modelling approaches (e.g., Wankmüller & Carminati, 2022) as well as taking advantage of longer term historical data to put ecohydrological drought in context (He et al, 2022). This includes—among others—relying on isotopic methods on specific ecohydrological contexts (e.g., Mattei et al, 2022), more widespread use of sensor technologies (Belmonte et al, 2022; Northup et al, 2022), novel remote sensing opportunities (Dugdale et al, 2022) and existing remotely sensed data (Mokhtar et al, 2022), and newly applied or developed statistical methods (Parolari & Paschalis, 2022), or machine learning/AI tools for processes that we currently do not incorporate well in physically‐based models of ecohydrological processes (Razavi et al, 2022).…”

Section: Need For Revised Ecohydrological Perspective On Droughtmentioning

confidence: 99%

Ecohydrological interactions during drought

et al. 2022

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Section: Need For Revised Ecohydrological Perspective On Droughtmentioning

confidence: 99%

Ecohydrological interactions during drought

et al. 2022

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“…Although TIR cameras can only measure the water temperature at the surface, it is much less labor‐intensive for surveys covering a large spatial scale than direct observation using thermometers or fiber‐optic distributed temperature sensing (FO‐DTS) systems (Hare et al., 2015). For surveys of wide rivers, the spatial distributions of groundwater discharge zones and the stream temperature can be mapped by using a TIR camera mounted on an unmanned aerial vehicle (UAV), helicopter, or aircraft (Dugdale et al., 2022; Niwa, 2022; Rautio et al., 2015; Wilbur et al., 2020). Even for fifth‐order river sites, however, UAV‐based TIR sensing is less suitable for locating groundwater discharge points than handheld TIR imaging owing to their submeter scale and position beneath the riparian tree canopy (Briggs et al., 2022).…”

Section: Introductionmentioning

confidence: 99%

“…• Real-time thermal imaging helps find suitable sampling points of groundwater discharge differing in chemistry from stream water • Postprocessing of thermal video can easily map springs with thermal anomalies and the spatial distribution of the stream temperature • The water temperature of springs is useful for inferring their sources when multiple groundwater sources contribute to a stream and the stream temperature can be mapped by using a TIR camera mounted on an unmanned aerial vehicle (UAV), helicopter, or aircraft (Dugdale et al, 2022;Niwa, 2022;Rautio et al, 2015;Wilbur et al, 2020). Even for fifth-order river sites, however, UAV-based TIR sensing is less suitable for locating groundwater discharge points than handheld TIR imaging owing to their submeter scale and position beneath the riparian tree canopy (Briggs et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

Real‐Time Monitoring and Postprocessing of Thermal Infrared Video Images for Sampling and Mapping Groundwater Discharge

Iwasaki

Fukushima

Nagasaka

et al. 2023

Water Resources Research

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Groundwater discharge along channels can affect stream discharge, chemistry, and ecological communities. Although the spatial distribution of groundwater springs along wide rivers can be investigated by areal thermal infrared (TIR) remote sensing, this technique is difficult to apply to mapping at a high spatial resolution and under riparian tree canopies. We present a real‐time monitoring and postprocessing method of ground‐based TIR video for determining groundwater discharge sampling points and mapping the surface water temperature. We applied this method to mapping two headwater streams in Hokkaido, Japan, in the summer. The first site was a 1.3‐km‐long reach underlain by Pleistocene andesite lava. Almost all of the springs were colder and had a different chemistry compared to that of the stream water, which supports the usefulness of TIR monitoring for determining groundwater discharge zones. Video postprocessing showed that cold groundwater springs were spaced every ∼100 m, and their distribution did not follow the topography. At the second site, cold and warm springs were underlain by Holocene volcanic ash. The cold springs mainly seeped from hyporheic and riparian zones downstream, while warm springs were at the footslope. Some cold springs had much higher solute concentrations than the stream and warm springs, which suggests that the water temperature is useful for inferring sources of groundwater discharge. At this site, the video postprocessing could map not only the locations of the cold springs but also the spatial heterogeneity of the stream temperature associated with groundwater inputs.

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“…Recent methodological developments, such as the deployment of flow presence-absence sensors and drone surveys (e.g. Dugdale et al, 2022;Carbonneau et al, 2020;Zanetti et al, 2022), provide important constraints, but tend to be limited in space or time. Water presence can be detected in large open water (Wang et al, 2022) bodies or main stem river reaches with width greater than existing satellite imagery pixel resolutions (∼10-30 m pixel, Wang et al, 2022;Qin et al, 2021;Verma et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Harnessing hyperspectral imagery to map surface water presence and hyporheic flow properties of headwater stream networks

Dralle¹,

Lapides²,

Rempe³

et al. 2022

Preprint

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Growth and contraction of headwater stream networks determine the extent and quality of ecologically critical habitat, and open a window into the storage dynamics of catchments. A fundamental challenge is observation of the process itself: wetted channel extent is highly dynamic in space and time, with the length of wetted channel sometimes varying by orders of magnitude over the course of a single storm event in headwater catchments. To date, observational datasets are produced from boots-on-the-ground campaigns, drone imaging, or flow presence sensors, which are often laborious and limited in their spatial and temporal extents. Here, we evaluate high-resolution, multi-band satellite imagery as a means to detect wetted channel extent via machine learning methods trained using existing wetted channel extent surveys. Even where channel features are smaller than the spatial resolution of the imagery, the absence or presence of surface water may nevertheless be imprinted upon the spectral signature of an individual pixel. We leverage existing wetted channel extent surveys at two oak savanna catchments in northern California with minimal riparian canopy cover and highly dynamic wetted channel extent due to small subsurface water storage capacity and saturation overland flow. We train a random forest model on high-resolution ($\sim$5 m pixel) RapidEye satellite imagery captured contemporaneously with the existing surveys. Withheld test data indicates prediction accuracy of wet vs. dry channel extent is $>$91\%. This predictive ability is used to produce length-discharge (L-Q) relations and to calculate spatially distributed estimates of channel hyporheic flow capacity and exchange. A sharp break in hyporheic flow properties occurs at the transition from main stem channels to lower order tributaries, resulting in a stepped L-Q relationship that cannot be captured by traditionally used power law models. Remotely sensed imagery is a powerful tool for producing wetted channel maps at high spatial resolution ($\sim$10 m in this study to channels with $>$ 0.01 km$^2$ contributing area).

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Looking to the Skies: Realising the Combined Potential of Drones and Thermal Infrared Imagery to Advance Hydrological Process Understanding in Headwaters

Cited by 19 publications

References 78 publications

Ecohydrological interactions during drought

Ecohydrological interactions during drought

Real‐Time Monitoring and Postprocessing of Thermal Infrared Video Images for Sampling and Mapping Groundwater Discharge

Harnessing hyperspectral imagery to map surface water presence and hyporheic flow properties of headwater stream networks

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