Snow process estimation over the extratropical Andes using a data assimilation framework integrating MERRA data and Landsat imagery

A data assimilation framework was implemented with the objective of obtaining high‐resolution retrospective snow water equivalent (SWE) estimates over several Andean study basins. The framework integrates Landsat fractional snow covered area (fSCA) images, a land surface and snow depletion model, and the Modern Era Retrospective Analysis for Research and Applications (MERRA) reanalysis as a forcing data set. The outputs are SWE and fSCA fields (1985–2015) at a resolution of 90 m that are consistent with the observed depletion record. Verification using in‐situ snow surveys showed significant improvements in the accuracy of the SWE estimates relative to forward model estimates, with increases in correlation (0.49–0.87) and reductions in root mean square error (0.316 m to 0.129 m) and mean error (−0.221 m to 0.009 m). A sensitivity analysis showed that the framework is robust to variations in physiography, fSCA data availability and a priori precipitation biases. Results from the application to the headwater basin of the Aconcagua River showed how the forward model versus the fSCA‐conditioned estimate resulted in different quantifications of the relationship between runoff and SWE, and different correlation patterns between pixel‐wise SWE and ENSO. The illustrative results confirm the influence that ENSO has on snow accumulation for Andean basins draining into the Pacific, with ENSO explaining approximately 25% of the variability in near‐peak (1 September) SWE values. Our results show how the assimilation of fSCA data results in a significant improvement upon MERRA‐forced modeled SWE estimates, further increasing the utility of the MERRA data for high‐resolution snow modeling applications.