Abstract
In viticulture, detailed spatial information about actual evapotranspiration (ETa) and vine water status within a vineyard may be of particular utility when applying site-specific, precision irrigation management. Over recent decades, extensive research has been carried out in the use of remote sensing energy balance models to estimate and monitor ETa at the field level. However, one of the major limitations remains the coarse spatial resolution in the thermal infrared (TIR) domain. In this context, the recent advent of the Sentinel missions of the European Space Agency (ESA) has greatly improved the possibility of monitoring crop parameters and estimating ETa at higher temporal and spatial resolutions. In order to bridge the gap between the coarse-resolution Sentinel-3 thermal and the fine-resolution Sentinel-2 shortwave data, sharpening techniques have been used to downscale the Sentinel-3 land surface temperature (LST) from 1 km to 20 m. However, the accurate estimates of high-resolution LST through sharpening techniques are still unclear, particularly when intended to be used for detecting crop water stress. The goal of this study was to assess the feasibility of the two-source energy balance model (TSEB) using sharpened LST images from Sentinel-2 and Sentinel-3 (TSEB-PTS2+3) to estimate the spatio-temporal variability of actual transpiration (T) and water stress in a vineyard. T and crop water stress index (CWSI) estimates were evaluated against a vine water consumption model and regressed with in situ stem water potential (Ψstem). Two different TSEB approaches, using very high-resolution airborne thermal imagery, were also included in the analysis as benchmarks for TSEB-PTS2+3. One of them uses aggregated TIR data at the vine+inter-row level (TSEB-PTairb), while the other is based on a contextual method that directly, although separately, retrieves soil and canopy temperatures (TSEB-2T). The results obtained demonstrated that when comparing airborne Trad and sharpened S2+3 LST, the latter tend to be underestimated. This complicates the use of TSEB-PTS2+3 to detect crop water stress. TSEB-2T appeared to outperform all the other methods. This was shown by a higher R2 and slightly lower RMSD when compared with modelled T. In addition, regressions between T and CWSI-2T with Ψstem also produced the highest R2.
Highlights
In a scenario of climate change and water scarcity, viticulturists will have to rely more on efficient irrigation management and adopting regulated deficit irrigation (RDI) strategies for successful grape production and wine quality [1,2,3,4]
This paper evaluates the use of two-source energy balance model (TSEB)-PT with sharpened land surface temperature (LST) images from Sentinel-2 and Sentinel-3 for supporting operational irrigation decision-making in a vineyard throughout a full growing season
Based on the previously mentioned studies, which pointed to a good level of agreement between crop water stress index (CWSI) and ΨL using very high-resolution airborne imagery and demonstrated its workability for scheduling irrigation, one hypothesis of this study focuses on whether the theoretically based CWSI—which is defined as one minus the ratio of T, over potential transpiration (T0) [24]—calculated with Sentinel data could provide an appropriate approach for detecting differences in vine water status
Summary
In a scenario of climate change and water scarcity, viticulturists will have to rely more on efficient irrigation management and adopting regulated deficit irrigation (RDI) strategies for successful grape production and wine quality [1,2,3,4] To achieve these targets, accurate estimates of actual evapotranspiration (ETa) and water status at the sub-field scale are necessary, for specialty crops. Several satellites have been used to estimate ETa based on thermal infrared (TIR) data, whose spatial and temporal resolutions may vary [8] Satellites such as Landsat (60-120 m), MODerate resolution Imaging Spectrometer (MODIS) (1 km), ASTER (90 m) and GOES (4 km) have been widely applied for mapping ETa in irrigated agricultural fields [9,10,11,12]. One inherent limitation is the need to detect crop water stress in cases in which crops, and those with heterogeneous or complex canopies, are stressed but without provoking a reduction in their leaf biomass
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