Abstract
Eddy covariance (EC) systems are being used to measure sensible heat (H) and latent heat (LE) fluxes in order to determine crop water use or evapotranspiration (ET). The reliability of EC measurements depends on meeting certain meteorological assumptions; the most important of such are horizontal homogeneity, stationarity, and non-advective conditions. Over heterogeneous surfaces, the spatial context of the measurement must be known in order to properly interpret the magnitude of the heat flux measurement results. Over the past decades, there has been a proliferation of ‘heat flux source area’ (i.e., footprint) modeling studies, but only a few have explored the accuracy of the models over heterogeneous agricultural land. A composite ET estimate was created by using the estimated footprint weights for an EC system in the upwind corner of four fields and separate ET estimates from each of these fields. Three analytical footprint models were evaluated by comparing the composite ET to the measured ET. All three models performed consistently well, with an average mean bias error (MBE) of about −0.03 mm h−1 (−4.4%) and root mean square error (RMSE) of 0.09 mm h−1 (10.9%). The same three footprint models were then used to adjust the EC-measured ET to account for the fraction of the footprint that extended beyond the field of interest. The effectiveness of the footprint adjustment was determined by comparing the adjusted ET estimates with the lysimetric ET measurements from within the same field. This correction decreased the absolute hourly ET MBE by 8%, and the RMSE by 1%.
Highlights
Measuring and modeling ET is difficult due to the nature of water vapor transport into the atmosphere
Because the crop height and leaf area index (LAI) were derived from five spot measurements throughout the study period, it is necessary to evaluate the spatial homogeneity of each field
This condition is rarely met when measuring fluxes over agricultural lands due to the typical patchwork of fields, each with a different crop, surface roughness, and water availability. It is the objective of this study to ascertain the effectiveness of analytical footprint models over such terrain, each field within this study needs to be reasonably homogeneous in order to Atmosphere 2021p, 1r2o, xpFeOrRlPyEEeRstRiEmVIaEWte the composite ET
Summary
Measuring and modeling ET is difficult due to the nature of water vapor transport into the atmosphere. Soil water balance is an affordable and relatively accurate method that can be used for irrigation scheduling. Remote sensing and satellite-based modeling holds great potential for practical application, since the process covers large areas that can be instantaneously available via the internet. Sap flow methods directly measure the transpiration through a plant, but large errors are introduced when attempting to scale up measurements to a field or regional scale. Managed lysimeters have the potential of measuring ET with high accuracy, according to Howell et al [2]. These instruments are large, expensive, and only provide the user with a measurement that represents a rather small area. The EC system has the advantage that it can be relocated, and that its derived sensible (H) and latent (LE) heat flux values are representative of the cropped field’s given heat flux source area
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