The surface model used in this study, GEOtop, is a physically based model originally developed for hydrological research . It couples energy and water budgets, represents the energy exchange with the atmosphere and has a multilayer snowpack. Further information is given by , , and . A description of model uncertainty and sensitivity is given by . Model parameters and soil stratigraphy are set up as defined in .

TopoSCALE is a scheme that generates point-scale model forcing using gridded atmospheric model datasets. It achieves this as follows: (1) data available on pressure levels, including air temperature (Ta), relative humidity (RH), wind speed (U) and wind direction (φU) are interpolated to a point of interest in order to provide a dynamic scaling at each time step; (2) incoming longwave radiation (L↓) is scaled by accounting for downscaled Ta, RH and sky emissivity; (3) we apply a topographic correction to both radiation fields (S↓/L↓); and (4) an elevation based lapse rate is applied to precipitation (P). The output is a full set of scaled meteorological fields required to drive a numerical model at hourly time steps.

TopoSUB is a scheme that samples land surface heterogeneity at high resolution based on a digital elevation model (DEM) and other surface data (here SRTM 3, 30 m). Input predictors describing dimensions of variability are clustered with a k-means algorithm to reduce computational units in a given simulation domain to a set of clusters. A 1-D surface model is then applied to each cluster using its mean physiographic properties. This approach allows savings in computational effort of multiple orders of magnitude over distributed approaches. For example, a simulation domain represented by an ERA5 grid cell (31 km × 31 km) contains approximately 106 SRTM 3 pixels. This domain can be simulated using 100 TopoSUB clusters, which represents a 104 reduction in the computational load during simulation.

We build on previous efforts e.g. that focus on the reanalysis of snowpack characteristics (particularly SWE and height of snow, HS) through ensemble-based assimilation of fractional snow covered area (fSCA) retrievals from optical satellite sensors. We choose to use fSCA retrievals because currently only optical satellite sensors can offer the resolution, coverage, accuracy and breadth of information needed to constrain snowpack simulations in complex terrain see. We use fSCA retrieved from the MODIS sensors onboard the Aqua and Terra satellites. These retrievals have a sub-kilometric spatial resolution and a near-daily equatorial revisit frequency (in the absence of clouds); thus, the reanalysis we perform could be applied to any mountain range on Earth. By assimilating fSCA observations we exploit the dynamic information content contained in the depletion of the fractional snow cover. The idea is that if one grid cell melts out later than another, there must either have been more snow there to begin with, a slower ablation, or a combination of the two – and vice-versa for an earlier melt out . This is the essence of traditional snow reconstruction where the snowpack is contrived in reverse from the observed date of disappearance of the snow cover to the day of peak SWE using modelled snowmelt rates . By using ensemble-based DA we can account for uncertainties in the remotely sensed fSCA depletion, the meteorological forcing and the snow model that are ignored in traditional reconstruction and arrive at an improved reanalysis . Snow reanalysis problems are best approached using batch smoother DA algorithms rather than the more commonly used filters as the snowpack has a long memory (i.e. high temporal autocorrelation) relative to (e.g.) synoptic-scale weather . By using a smoother that assimilates all of the fSCA retrievals during the ablation season at once to constrain the ensemble of annual snowpack trajectories, we are able to use the observed ablation to inform the accumulation season which would not be possible with a particle filter.

Driving climate data are obtained from the ERA5 reanalysis from ECMWF. This is the latest reanalysis from ECMWF that updates the ERA-Interim reanalysis. The main improvements are an increase in the spatial resolution to 31 km, hourly temporal resolution and an increase in the vertical model levels to 137. Accumulated values are now from the last time step and not from the last forecast as in ERA-Interim. This means that we can easily obtain the mean rates required to drive our numerical model by simply dividing these accumulations by the hourly time step . Forcing data are detailed in Table 2. For each TopoSUB cluster, defined by the mean physiographic characteristics of a cluster, the ERA5 meteorological fields are downscaled using TopoSCALE .

TopoSUB requires topographical parameters as input predictors to the clustering algorithm. We derive the following topographic parameters from the SRTM 3 digital elevation model: elevation, slope, aspect and sky view factor (proportion of visible sky). Surface cover is characterized in a simple three-mode classification in order to approximate subsurface stratigraphies: first a threshold on MODIS normalized difference snow index (NDSI) is used to classify vegetated surfaces, then a simple model further differentiates between steep bedrock and debris slopes. Further details are available in .

We assimilate fSCA retrievals obtained from version 6 of the level 3 daily MODIS snow cover product from the Terra MOD10A1 product; and Aqua MYD10A1 product; satellites. The retrieval algorithm is based on the inversion of a linear regression of the MODIS NDSI on reference fSCA estimated from coincident Landsat imagery and it is given by the “FRA6T” relationship in . The normalized difference snow index exploits the fact that snow is highly reflective in the visible but a good absorber in the shortwave infrared which differentiates it from most other natural surfaces . If cloud-free retrievals are available from both Terra and Aqua retrievals for a given day then the Terra retrievals are used. compared MODIS fSCA retrievals to reference fSCA estimates obtained from time-lapse photography, imagery from an unmanned aerial vehicle and snow surveys at a site on Svalbard and obtained an RMSE of σy=0.13 for the MODIS retrievals. This estimate is in good agreement with those found in the Alps by other studies e.g.; thus, we use this as the observation error variance (σy2) in the assimilation (Sect. 2.3.2).

Point-scale DA is accomplished by simply mapping the DEM cell corresponding to point of interest (e.g. a validation station) to the corresponding MODIS pixel for that location. The Wp derived from the PBS analysis for that MODIS pixel is then used directly to generate the posterior estimate for that point. Model state results are obtained from the TopoSUB cluster that the DEM cell is a member of. Cumulative distributions of state variables are computed through the ranking of the ensemble of state variables followed by a cumulative summation of the correspondingly sorted weights. These distributions allow for the estimation of quantile values of the posterior model state.

The particle batch smoother has typically been applied at the point scale or on regular grids. Here we generalize the method so as to fit the TopoSUB approach. The basic aim is to generate posterior weights for each TopoSUB cluster (which has no location, only physiographic attributes) so that the weights can be used in a highly scalable and powerful manner to generate different products such as a time series of the posterior median aggregated to give basin-level statistics. The key challenge in this aim is how to map the spatial unit of the PBS algorithm, the MODIS pixel, which has a location in space, to a TopoSUB cluster which does not. We achieve this via the following: 3wc=Wp⋅a, where Wp is the Ne×Np weights matrix and a is a Np×1 vector containing the fractional abundance (cover) of cluster c represented in each of the MODIS pixels. Here wc contains the weight of each forcing history for cluster c and is computed for each of the clusters. This yields the weights matrix wc that contains the weights of the forcing histories for each cluster. As a second step the weights wc are renormalized to sum to one as that is not guaranteed in Eq. (3).

The third DA method addresses bias in forcing at the grid level only, and it is the most efficient and lightweight of the three approaches. It also differs from the previous methods in that the PBS analysis step is computed at the ERA5 grid unit not at the MODIS pixel unit. This makes the analysis step highly efficient and scalable over large areas. It is emphasized that while the two previous methods address both aggregated bias in forcing at the grid level and also correct errors in the sub-grid method (such as physiographic description) and downscaling (such as precipitation distribution), this method only corrects the bias at the grid level. However, it is of interest if we seek a simple and robust way to feedback sub-grid information to large-scale atmospheric grid cells, in this case using ERA5. The method is carried out as follows:

MODIS fSCA is computed aggregated to the large-scale atmospheric grid cell (ERA5) while accounting for clouds (max 10 % cloudiness tolerated), and cloud pixels are then filled with the mean fSCA value of the cluster to which the pixel belongs;

All runs are performed using 100 particles, 150 TopoSUB clusters and cover the period from 1 September 2011 to 1 September 2017. The specific temporal period covered by a given result is defined in the text. Throughout the paper a single year refers to the year in which melt occurs, e.g., “2012” refers to the period from 1 September 2011 to 1 September 2012. These “water years” are prefixed with WY (e.g. WY2012) to avoid ambiguity. We measure computational effort through the number of GEOtop model runs (Nr) required per year in an ERA5 grid cell. Recall that the ERA5 grid cell is the fundamental unit on which the downscaling and clustering is performed. In terms of the number of clusters (Ns) and particles (Ne), this effort becomes 4Nr=Ne×Ns. In the case of the configuration used in this study (Ne=100, Ns=150), this amounts to 1.5×104 individual model runs. At a 30 m resolution, there are 106 model grid cells within a single 0.25∘ ERA5 grid cell. Thus, an explicit fully distributed simulation with 100 particles would require Nr=108, which is a 4 order of magnitude increase in computational effort relative to the set-up used in this study.

Figure  shows performance of the forward model at the Weissfluhjoch (WFJ) research site (see Fig.  for position) assessed over the period from WY2012 to WY2017. It illustrates the performance of the downscaling routine with respect to providing an adequate forcing to the model (forcing bias) and the performance of the model in simulating the target variables, SWE and HS, when driven by downscaled ERA5 reanalysis (revealing model and forcing errors) and station observations (revealing model and observation errors). It shows that the TopoSCALE downscaling routine does a reasonable job of providing forcing to the forward model (Fig. 3a–e) with a 0.71 ∘C RMSE for 2 m air temperatures being particularly low. Conversely, high wind velocities tend to be positively biased, most likely as wind fields representing the free atmosphere on pressure levels have no surface drag that would be present in surface observations. Modelled HS and SWE (Fig. 3f–i) are captured fairly well, reproducing both the onset and melt of the snowpack. However, peak values are generally negatively biased with respect to observations and station-driven model runs. WY2012 is an obvious outlier with large snowfalls not captured by ERA5 precipitation. This can be seen by cumulative precipitation totals computed with and without WY2012 totals (Fig. ). This is reflected in simulated HS and SWE totals. The performance of the forward model can be analysed by driving the simulations with station measurements to remove most of the uncertainty associated with driving reanalysis data (but with residual observation errors). ERA5-driven simulations are comparable or even outperform station runs in WY2013 and WY2014.

In this experiment we compare the prior and (single-pixel) posterior HS and SWE for WY2016 to the measured values at the respective stations. An example at Truebsee GCOS station (Engelberg) is shown in Fig. . This figure demonstrates the effect that the assimilation has not only on the fSCA (which is assimilated), but also on estimates of the other state variables (in this case SWE) which get closer to independent observations. Here one can clearly see how the posterior estimate of SWE (blue shading) is constrained by the assimilation, and the posterior median (blue line) is much closer to validation SWE observations than the prior (red line). We then scaled this up to nine ERA5 grid boxes that span the Swiss Alps and contain 11 GCOS SWE stations. Additionally each box contains multiple IMIS stations measuring HS, which we also looked at in the interest of obtaining more validation data. Significant improvements in the posterior were seen in the estimation of both variables (Fig. ). We found that the improvement in the SWE was greater than that in the HS. We hypothesize that this is due to representation of snow densities in the snow model. However, the improved representation of the snowpack mass balance as shown by improved SWE estimates is the main variable of interest in our approach. Stations where DA performed worse than the prior can be attributed to poorly characterized melt seasons, lack of MODIS retrievals and/or the MODIS retrievals not being representative at the scale of the observations (cf. Sect. 6).

We evaluated the performance of the method in improving the spatial patterns and absolute quantities over large areas using data from an airborne digital sensor which has been used to generate high-resolution surfaces of HS in WY2012, WY2013 and WY2014 (Fig. , WY2014 only). Both WY2012 and WY2014 show marked improvement in all spatial statistical measures including the mean value, the standard deviation (indicating increased variation) and error statistics such as the RMSE and bias. WY2013 shows little improvement. We would expect a better performance for SWE than for HS due to the previously mentioned issues with the modelled snow density (see Sect. 5.2 and Fig. 5). Figure 6 shows how the 90th percentile range is constrained by the analysis going from the prior to the posterior. Figure  shows probability density distributions for observations, prior and posterior in WY2014. The shape and moments, such as the mean, more closely match the observations in the posterior distribution. However, the method fails to capture the very highest accumulations in the distribution (>2.5 m), possibly due to the averaging effects of generalizing weights to TopoSUB clusters.

Aggregated series of observed and modelled fSCA are computed at the ERA grid level. This could equally be a hydrological unit such as a basin. The main idea is to correct grid-level biases in the forcing only. If we assume this is the main source of uncertainty, especially with a view to correcting large-scale biases, this is an effective method to apply at the scale of meteorological reanalysis. Data from WFJ are used to illustrate this point. Figure  shows two contrasting snow seasons – WY2012 (high) and WY2014 (low) – where mean snow depths and SWE differed by a factor of 2, as recorded at WFJ (Fig. ). We compare the total ERA5 precipitation (PSUM) over the winter period January–April 2014 (401 mm) and compare it to totals recorded over the same period at the WFJ station (350 mm), ERA5 captures WFJ totals well. It should be added that there is some elevation difference between the ERA5 grid (2024 m a.s.l.) and the WFJ station (2560 m a.s.l.). However, in WY2012 we see quite a different story. The ERA5 grid gives us slightly higher PSUM values of 440 mm, whereas the measured PSUM was almost double this at 826 mm. Figure  shows how grid-level biases in the driving forcing from ERA5 have been successfully decreased in WY2012 resulting in increased SWE totals, whereas in WY2014 where ERA5 performance was much better (cf. Fig. ), DA has had a negligible effect. This simple approach is an extremely cost-effective method of assimilating slope-scale sub-grid information (in this case fSCA) to correct coarse grid-scale forcings (ERA5). It is additionally generic enough that it could be used with various other sub-grid observations, such as soil moisture, to improve grid-level responses.

Using the methods described in this paper, a range of processing pipelines can be built to address a wide array of both research and operational problems. Specific strengths of the approach are as follows:

there is slope-scale forcing (climate, reanalysis, forecast) globally;

Transient climate change studies using a combination of reanalysis and climate model data (e.g. CMIP5) would be a valuable research application based on this approach, for example quantifying dynamics of permafrost extent over large areas according to a range of scenarios and models or generating a regional snowpack reanalysis product with projected future changes.

An important operational application and currently a great humanitarian need in many remote regions in Asia (e.g. Afghanistan/Tajikistan) could be an operational avalanche forecast based on a snowpack model (e.g. SNOWPACK, CROCUS), driven by an NWP ensemble to generate a large area probabilistic forecast where few ground stations exist. This would be a relatively cost-effective system to deploy and give first-order hazard assessment where none currently exists.

For the moderate (MODIS-like) resolution satellites, we hope that products will emerge from Sentinel-3 and VIIRS to prolong and expand the MODIS record. For high-resolution sensors, there is a strong need for operational products that ideally combine available and emerging sources such as Landsat 8 and Sentinel-2. The French inter-agency initiative THEIA Land Data Centre is starting to produce Sentinel-2-based snow cover products , which – at both high temporal and spatial resolution – will likely prove to be a great product for data assimilation work. Additionally, improved cloud masks are needed as misclassified clouds are potential and significant sources of error in the framework. Both overly strict and overly relaxed cloud masking is problematic, the former leads to valid and potentially important retrievals being discarded, whereas the latter corrupts the signal that we are trying to assimilate (the actual snow cover depletion).

For additional datasets (other than fSCA), land surface temperature can be retrieved from both MODIS and Landsat and provide a means to constrain uncertainty in the surface energy balance. However, the current MODIS products are coarse at 1 km and, therefore, not ideal for mountain regions.

For additional datasets (other than fSCA), land surface temperature (LST) can be retrieved from both MODIS and Landsat and provide a means to constrain uncertainty in the surface energy balance. However, the current MODIS LST products are coarse at 1 km with respect to the expected heterogeneity of LST in mountain regions . Snowmelt status (i.e. binary melting/not melting) from synthetic aperture radar (SAR) e.g. Sentinel-1 has the potential to constrain uncertainty in the fSCA during cloudy periods. There is also potential from ICESat-2 which could provide a way to constrain snow depth directly .

Assimilation of sparse point data could be an important extension of this work to provide means to assimilate data sources such as ICESat-2 but could also be used to improve TopoSCALE by assimilating point data (stations) to improve the downscaling of reanalysis data. This could be interesting as TopoSCALE performs most poorly is in valleys, where surface effects are poorly represented by the atmospheric model, and this is precisely where stations tend to be most abundant globally. For real-time applications in remote regions, extending the method to assimilate sparse observations is important as fSCA is known to have limited value in sequential (i.e real-time) data assimilation. We have shown that there is some interannual validity of results in our limited test case, suggesting that systematic biases relevant to real-time applications could be addressed through reanalysis. Additionally, creating a long-term library of “best possible” reconstructions/reanalyses and then training an “analogue ensemble” or even a more machine-learning-type approach (like neural nets) could be promising.