Peace-Athabasca Delta water surface elevations and slopes mapped from AirSWOT Ka-band InSAR

In late 2023 the Surface Water and Ocean Topography (SWOT) satellite mission will release unprecedented high-resolution measurements of water surface elevation (WSE) and water surface slope (WSS) globally. SWOT's exciting Ka-band near-nadir wide-swath interferometric radar (InSAR) technology co...

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Bibliographic Details
Published in:Remote sensing letters 2023-12, Vol.14 (12), p.1238-1250
Main Authors: Smith, Laurence C., Fayne, Jessica V., Wang, Bo, Kyzivat, Ethan D., Gleason, Colin J., Harlan, Merritt E., Langhorst, Theodore, Feng, Dongmei, Pavelsky, Tamlin M., Peters, Daniel L.
Format: Article
Language:English
Subjects:
AirSWOT
Avulsion
Coastal inlets
Data acquisition
Data loss
Discharge measurement
Extremely high frequencies
Gaging stations
Hydrology
Interferometric synthetic aperture radar
Lakes
Radar
radar remote sensing
river avulsion
River flow
Rivers
Stream discharge
Surface water
SWOT
Water level fluctuations
Water levels
Water surface slope
wetlands
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Summary:In late 2023 the Surface Water and Ocean Topography (SWOT) satellite mission will release unprecedented high-resolution measurements of water surface elevation (WSE) and water surface slope (WSS) globally. SWOT's exciting Ka-band near-nadir wide-swath interferometric radar (InSAR) technology could transform studies of surface water hydrology, but remains highly experimental. We examine Airborne SWOT (AirSWOT) data acquired twice over Canada's Peace-Athabasca Delta (PAD), a large, low-gradient, ecologically important riverine wetland complex. While noisy and susceptible to "dark water" (low-return) data losses, spatially averaged AirSWOT WSE observations reveal a broad-scale water-level decline of ~44 cmn (σ =271 cm) between 9 July and 13 August 2017, similar to a ~56 cm decline (σ=33 cm) recorded by four in situ gauging stations. River flow directions and WSS are correctly inferred following filtering and reach-averaging of AirSWOT data, but ~10 km reaches are essential to retrieve them. July AirSWOT observations suggest steeper WSS down an alternate flow course (Embarras River-Mamawi Creek distributary) of the Athabasca River, consistent with field surveys conducted the following year. This signifies potential for the Athabasca River to avulse northward into Mamawi Lake, with transformative impacts on flooding, sedimentation, ecology, and human activities in the PAD. Although AirSWOT differs from SWOT, we conclude SWOT Ka-band InSAR observations may detect water level changes and avulsion potentials in other low-gradient deltas globally.
ISSN:2150-704X
2150-7058
DOI:10.1080/2150704X.2023.2280464