Abstract
Spatial patterns in long-term average evapotranspiration (ET) represent a unique source of information for evaluating the spatial pattern performance of distributed hydrological models on a river basin to continental scale. This kind of model evaluation is getting increased attention, acknowledging the shortcomings of traditional aggregated or timeseries-based evaluations. A variety of satellite remote sensing (RS)-based ET estimates exist, covering a range of methods and resolutions. There is, therefore, a need to evaluate these estimates, not only in terms of temporal performance and similarity, but also in terms of long-term spatial patterns. The current study evaluates four RS-ET estimates at moderate resolution with respect to spatial patterns in comparison to two alternative continental-scale gridded ET estimates (water-balance ET and Budyko). To increase comparability, an empirical correction factor between clear sky and all-weather ET, based on eddy covariance data, is derived, which could be suitable for simple corrections of clear sky estimates. Three RS-ET estimates (MODIS16, TSEB and PT-JPL) and the Budyko method generally display similar spatial patterns both across the European domain (mean SPAEF = 0.41, range 0.25–0.61) and within river basins (mean SPAEF range 0.19–0.38), although the pattern similarity within river basins varies significantly across basins. In contrast, the WB-ET and PML_V2 produced very different spatial patterns. The similarity between different methods ranging over different combinations of water, energy, vegetation and land surface temperature constraints suggests that robust spatial patterns of ET can be achieved by combining several methods.
Highlights
Actual evapotranspiration (ET) is a key hydrological flux that together with precipitation determines the upper limit of the water resources available to sustain human needs and freshwater ecosystems
The goal of this study is to evaluate the spatial pattern consistency of long-term average ET among the remote-sensing-based estimates at a moderate resolution (1 km) and compare them to alternative ET estimates derived from Budyko [23,24] and water-balance (WB-ET) [25] approaches at a resolution of 25 km
The spatial distributions of long-term annual mean evapotranspiration estimated from the water-balance approach (WB-ET) and the empirically based Budyko approach (Budyko ET) are illustrated in Figure 6a,b, respectively
Summary
Actual evapotranspiration (ET) is a key hydrological flux that together with precipitation determines the upper limit of the water resources available to sustain human needs and freshwater ecosystems. Despite intense research and methodological development, ET continues to be one of the most difficult hydrological states and fluxes to measure, especially on large spatial scales. 2021, 13, 2410 on large spatial scales, which has turned the focus of such estimations towards satellite remote sensing [3]. Sensors onboard satellites cannot measure ET directly, satellite data offer the opportunity to measure a range of relevant variables, such as land surface temperature, albedo and vegetation cover. Based on these measurements, several methods, models and algorithms have been developed that estimate ET at the spatial coverage and spatial and temporal resolution of the native satellite data
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