Abstract
Thermal infrared remote sensing observations have been widely used to provide useful information on surface energy and water stress for estimating evapotranspiration (ET). However, the revisit time of current high spatial resolution (<100 m) thermal infrared remote sensing systems, sixteen days for Landsat for example, can be insufficient to reliably derive ET information for water resources management. We used in situ ET measurements from multiple Ameriflux sites to (1) evaluate different scaling methods that are commonly used to derive daytime ET estimates from time-of-day observations; and (2) quantify the impact of different revisit times on ET estimates at monthly and seasonal time scales. The scaling method based on a constant evaporative ratio between ET and the top-of-atmosphere solar radiation provided slightly better results than methods using the available energy, the surface solar radiation or the potential ET as scaling reference fluxes. On average, revisit time periods of 2, 4, 8 and 16 days resulted in ET uncertainties of 0.37, 0.55, 0.73 and 0.90 mm per day in summer, which represented 13%, 19%, 23% and 31% of the monthly average ET calculated using the one-day revisit dataset. The capability of a system to capture rapid changes in ET was significantly reduced for return periods higher than eight days. The impact of the revisit on ET depended mainly on the land cover type and seasonal climate, and was higher over areas with high ET. We did not observe significant and systematic differences between the impacts of the revisit on monthly ET estimates that are based on morning or afternoon observations. We found that four-day revisit scenarios provided a significant improvement in temporal sampling to monitor surface ET reducing by around 40% the uncertainty of ET products derived from a 16-day revisit system, such as Landsat for instance.
Highlights
Evapotranspiration (ET) represents the loss of water from the Earth’s surface by evaporation of water intercepted by the soil surface and the canopy, and by vegetation transpiration processes
The analysis of different scaling methods showed that the daytime self-preservation of evaporative ratios based on the available energy (AE), surface solar radiation (RG), top-of-atmosphere irradiance (RTOA) or potential evapotranspiration reference (PET) fluxes was usually not verified throughout the year for all the sites as already noted by other authors, such as References [4,36,43], for example
We found that the different methods performed relatively well and the observed differences with ground-based measurements were associated with low median errors and median absolute deviations
Summary
Evapotranspiration (ET) represents the loss of water from the Earth’s surface by evaporation of water intercepted by the soil surface and the canopy, and by vegetation transpiration processes. ET may be derived by taking advantage of remotely sensed observations of surface variables that are linked to ET. Thermal infrared radiometers at km-scale resolution, such as the Moderate Resolution Imaging Spectroradiometer (MODIS) at 1 km or the Visible Infrared Imaging Radiometer Suite (VIIRS) at 750m resolution, provide daily and spatially continuous information about the land surface temperatures that are commonly used to derive ET and drought indices at large scales [8,9,10,11]. Spaceborne systems must be able to capture rapid changes in land surface temperature (LST) after a precipitation or irrigation event [16] requiring high spatial resolution observations on a frequent basis.
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