Abstract
The determination of evapotranspiration (ET) using ground-based meteorological data does not adequately capture the spatial patterns of mass and energy fluxes in mountainous areas. In this work, we evaluate the daily spatial distribution of ET over a mountainous watershed in southeastern Brazil by coupling Surface Energy Balance Algorithms for Land (SEBAL), a global solar radiation (GSR) model, and a gridded weather dataset (GWD). To estimate daily tilted GSR, we use the relation between terrain and sun angles over a 24-h integration time. Tests were performed in summer/wet (12 January 2015) and winter/dry (25 September 2015) periods to evaluate the seasonal differences in ET over tilted surfaces. The results indicated different spatial patterns of daily ET on the watershed in each period. In summer, ET was 9.8% higher on slopes facing South, while in winter, ET was 10.6% higher on slopes facing North and East. A high variability in daily ET was found on steeper slopes (above 45°) in both periods. The notable ET spatial heterogeneity indicates the complex partitioning of mass and energy fluxes from different terrain angles, which may influence hydroecological processes at the local scale. The presented approach allowed a more detailed capture of the spatial variability of ET in a mountainous watershed with scarce ground-based data.
Highlights
On mountainous and heterogeneous landscapes, evapotranspiration (ET) estimations using remote sensing becomes more complex, due mainly to the difficulties with estimating net radiation in different slopes and terrain azimuths, and the uncertainties regarding energy and mass transfer processes, such advection and local wind flow.Some authors have developed techniques to evaluate the influence of topography on actual ET estimate by remote sensing [1], as well as on reference ET [2] and surface energy fluxes [3]
The correted net radiation for tilted surfaces was obtained from parameterizations using global solar radiation (GSR) modeling, considering different slopes and azimuths of terrain
We evaluate the daily spatial distribution of ET over a mountainous watershed in southeastern Brazil in summer/wet and winter/dry periods, by coupling Surface Energy Balance
Summary
Some authors have developed techniques to evaluate the influence of topography on actual ET estimate by remote sensing [1], as well as on reference ET [2] and surface energy fluxes [3]. In these applications, the correted net radiation for tilted surfaces was obtained from parameterizations using global solar radiation (GSR) modeling, considering different slopes and azimuths of terrain. Proceedings 2018, 2, 342 especially in areas with high weather/environmental variability This issue was addressed by [4] in an approach using raster meteorological data as input to the Surface Energy Balance Algorithms for
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