The calculation of the SWnet radiation takes into account (i) the topographic effects affecting the SW radiation and (ii) the spectral dependence of snow albedo and incident solar irradiance. The aim is to compute it on every facet f due to the direct and diffuse components of the solar irradiance: 2SWnet,f(θs)=SWnet, dir,f(θs)+SWnet, diff,f3SWnet, dir,f(θs)=∫λ0λ1Adir,f(λ,θs)Idir(λ)dλ4SWnet, diff,f=∫λ0λ1Adiff,f(λ)Idiff(λ)dλ, where the direct and diffuse components of the absorbed SW radiation by every facet are computed using (i) an absorption coefficient Adir, diff,f, derived from the RSRT model, and (ii) the spectral irradiance coming from the sky Idir, diff(λ), issued from the SBDART model. The integration is between λ0=300 nm and λ1=4200 nm to cover all the solar radiation spectrum.

A direct way to compute the absorbed SW radiation by each facet would be to use the ray-tracing RSRT model to trace many photons for every wavelength in the solar spectrum. Nevertheless, with millions of facets and hundreds of wavelengths, this approach would imply an enormous computational cost due to the inefficiency of the Monte Carlo ray-tracing method. To overcome this, we take advantage of the result of the RSRT model to account for multiple bouncing. In this model, each launched photon has an initial propagation direction specified by the zenith and azimuth angles and a random initial position above the mesh. The intersection between the photon direction and the mesh surface is first calculated. Then, to simulate a Lambertian reflection, the change in direction is taken randomly from the cosine-weighted hemispherical distribution. The algorithm iterates as long as the photon propagates from facet to facet and stops only when the photon escapes from the domain or when a maximum number of bounces is reached (noted nmax). No albedo and no absorption are involved at this stage; RSRT only computes possible geometric trajectories of photons in the given mesh. The number of photons launched is 4×108, and edge effects are avoided by excluding the outermost 15 % of the mesh area.

The RSRT model records the number of times photons have hit a given facet as a function of the bounce order of the photon (first reflection, second reflection, …). It is hereafter noted nhit, d,f(i) and corresponds to the proportion of photons that directly hit the facet at their ith reflection (from i=0, and d is dir or diff depending on the illumination conditions – direct or diffuse). Assuming that the area has a uniform albedo (same snow properties everywhere in the domain) and that the reflections are Lambertian, the absorption coefficient Adir, diff,f is computed by taking into account (i) the spectral dependence of snow albedo and (ii) the fact that the illumination received by each facet is the sum of the illumination from photons at their first reflection and the multiple bounce contribution, considered to be diffuse illumination from photons at their second reflection, third reflection, etc. The coefficient is determined with 5Adir,f(λ,θs)=1-αdir(λ,θs)nhit, dir,f(0)+1-αdiff(λ)αdir(λ,θs)⋅∑i=1i=nmaxαdiffi-1(λ)nhit, dir,f(i)6Adiff,f(λ)=1-αdiff(λ)∑i=0i=nmaxαdiffi(λ)nhit, diff,f(i), where θs is the local solar zenith angle, and αdir, diff(λ,θs) is the snow spectral albedo under direct and diffuse illumination. Here, these albedos are computed using the asymptotic radiative transfer (ART) theory , whose formulation is presented in the Appendix . The calculation needs the snow specific surface area (SSA) as input. If not specified, a standard value of 20 m2kg-1 is assumed in the modelling.

The spectral irradiance coming from the sky Idir, diff(λ) is computed with the SBDART model. This model computes the atmospheric transmission and scattering (Mie theory). The simulations are run in the spectral range 300–4200 nm by steps of 3 nm. Here, a generic mid-latitude winter atmospheric profile is assumed, and the aerosol optical depth at 550 nm is 0.08 (“rural” profile in SBDART). The elevation is 2052 m a.s.l. (see Sect. ), and solar zenith and azimuth angles correspond to the desired date and time.

The net broadband SW radiation of each facet is eventually calculated by means of Eq. ().

To compute the incident LW flux from the atmosphere on each facet, we first apply a local correction to the observed downward LW flux (noted LWd, obs), measured in a single point of the domain (Sect. ). This correction takes into account the LW variations in altitude over the whole domain using the same approach as in . The correction consists of deriving an “effective emissive temperature” of the sky (noted Tsky, obs) from the measured LW flux with the Stefan–Boltzmann equation. This temperature is corrected for changes in elevation by introducing the lapse rate Γ: 7LWd, obs=σTsky, obs48Tsky,f=Tsky, obs+Γ(zf-zobs), with σ the Stefan–Boltzmann constant and where Tsky,f is the effective emissive temperature of the atmosphere above each facet. We choose Γ=-6.5 ∘Ckm-1, the environmental lapse rate as defined in the International Standard Atmosphere . The downwelling LW flux incident on each facet (LWd,f) is then recalculated with the Stefan–Boltzmann equation: 9LWd,f=σTsky,f4. In complex terrain facets receive radiation not only from the atmosphere but also from the surrounding slopes. Computing this contribution requires the facet surface temperature, which is precisely unknown. We proceed by iteration in two steps: in the first step, we neglect the thermal emission from the surrounding facets. This leads to a first estimate of the surface temperature (Sect. ) that is then used in the second step to account for the emission of surrounding terrain. The average upwelling LW flux from each facet (LWu, scene average) is computed from the average surface temperature of the whole domain with the Stefan–Boltzmann equation. This thermal emission is a constant; we neglect the possible variations in temperature around each facet. The updated downwelling LW flux on each facet is eventually calculated with 10LWd,f,updated=VfLWd,f+(1-Vf)LWu, scene average, where Vf is the sky-view factor calculated with RSRT. Vf is different for each facet: those in the valley receive more LW radiation from the surrounding slopes than facets at the summits of the domain. The sky-view factor is indeed equal to the proportion of the launched photons hitting a facet on their first bounce in diffuse illumination, namely Vf=nhit, diff,f(0).

The upwelling long-wave radiation, LWu,f, is determined by the Stefan–Boltzmann law: 11LWu,f=ϵσTs4+(1-ϵ)LWd,f, with snow emissivity ϵ=0.98 and Ts the snow surface temperature of the facet.

While the main focus of this work is on the role of the topographic effects controlling the radiation budget of the surface, the turbulent heat fluxes also need to be assessed to close the surface energy budget. We follow a simple modelling approach; potential improvements are left to further work in the future. The sensible and latent heat fluxes are calculated following the one-level approach: 12Hf=ρaircp,airCHU(Ts-Tair)13Lf=LsρairCHU⋅(qsat(Ts,Ps)-qair), where ρair and cp,air are the density and heat capacity of the air; U is the wind speed, Tair is the air temperature; Ls is the sublimation heat; qsat(Ts,Ps) is the saturation specific humidity at the snow surface, with surface temperature Ts and pressure Ps; and qair is the specific humidity at the level where air temperature and humidity are measured. CH is a surface exchange coefficient which in principle depends on atmospheric stability. For the sake of simplicity, a neutral situation is considered here. CH therefore depends only on the aerodynamic roughness length z0, assumed constant across the domain and equal to 10-3 m following previous works . The expression of this coefficient is provided in the Appendix , and the values of the defined symbols are presented in Table . The air temperature and wind speed are taken from the meteorological station (Sect. ). Tair accounts for the variations in altitude within the domain in a similar way as the downward LW flux (Sect. ), via a lapse rate effect (Eq. ). Wind speed and relative humidity are however considered constant. Note that the specific humidity is deduced from the relative humidity and air temperature, so it indirectly depends on altitude.

The ground heat flux (G) is neglected here as the snowpack is considered thermalized. We assume that no energy is exchanged with the snowpack, which is checked in the discussion (Sect. ).

The equation of the surface energy budget (Eq. ) with explicit Ts dependencies is 14SWnet,f+LWd,f,updated-LWu,fTs4+HfTs+Lfqsat(Ts)=0. The equation is solved to determine the unknown Ts for each facet f. However this equation is non-linear due to the Ts4 term (upwelling LW radiation) and the complex dependence of the saturation specific humidity at the surface to Ts. Solving such an equation for millions of facets can be computationally intensive. To avoid this issue, we linearize the specific humidity at saturation about Tair, as in : 15qsat(Ts,Ps)=qsat(Tair,Ps)+(Ts-Tair)⋅qsat′(Tair,Ps), where 16qsat′(Tair,Ps)=qsat(Tair,Ps)-qsat(Tair-ΔT,Ps)ΔT, with ΔT=5 K. The simplified surface energy budget equation eventually becomes a quartic equation for Ts of the form 17aTs4+dTs+e=0, where a, d, and e are a constant (for each facet). The general solution of this equation is shown in the Appendix . The evaluation of this equation for a large number of facets is computationally efficient compared to using a non-linear optimization solver.

Figure b shows Landsat 8 observations and snow surface temperature simulations compared to the in situ measurements at FluxAlp. The RoughSEB model is in general in agreement with the satellite observations. Considering all the images, they differ by up to 1 ∘C, the simulations being slightly warmer. The differences are however larger when considering the coldest cases, up to 5 ∘C. The error in the simulations is lower, 1.2 ∘C RMS (2.0 ∘C for Landsat observations).

The modelling chain to estimate Ts is evaluated over a diurnal cycle at the FluxAlp station (Fig. ). A period of ≈36 h was selected after one of the Landsat 8 acquisition dates, starting at 09:00 UTC on 10 March 2016. This period featured stable conditions, and the sky was clear, except for a few minutes at the end of the period. Figure  (top) shows the temporal evolution of the radiative fluxes (SWnet and LWnet) and the turbulent fluxes (sensible heat flux H and latent heat flux L). The simulations are run hourly, with a constant SSA =20 m2kg-1 and aerodynamic roughness length z0=10-3 m. The radiative fluxes are compared to the in situ measurements at the station, and the simulated turbulent heat fluxes are shown for completeness. It should be recalled that the simulations are run with a spectral range 300–4200 nm for the SW in order to cover the entire solar radiation spectrum. However, for a fair comparison with the measured SWnet, additional SW calculations are run in the same spectral range of the pyranometer (300–2800 nm). As measurements at the FluxAlp station are averaged over the preceding 30 min, a 15 min time shift is applied on the graph. The results show that the net short-wave flux is slightly underestimated except during the first hours of sunlight, when it is overestimated. The difference is almost negligible (<5 Wm-2) around 10:00–10:30 UTC, which by chance corresponds to the Landsat 8 acquisition time. The underestimation leads to an overall bias over daytime of ≈5 Wm-2, while the net long-wave radiation flux is in general overestimated by ≈7 Wm-2. Figure  (bottom) shows the evolution of the simulated Ts over the same period compared to the in situ measurements. Observed air temperature is also shown for completeness. There is a good agreement between the simulations and the measurements, within 0.2 ∘C (RMSE: 0.8 ∘C). Surface temperature shows a diurnal cycle, where the melting point is barely reached in the early afternoon, and the lowest temperatures are reached at night. The bias in Ts towards the end of the afternoon could be explained by the balance between the underestimation of the net SW flux and the overestimation of the net LW flux. The slight variations in surface temperature (around 2 to 3 ∘C) during the night are mainly driven by the balance between the long-wave radiation flux and the sensible heat flux, the other fluxes being negligible.

To evaluate the spatial variations in Ts, the simulation corresponding to the Landsat 8 acquisition on 18 February 2018 is analysed here. It is chosen because in situ SSA measurements were available , allowing a more accurate estimate of the surface albedo. The SSA value is 45 m2kg-1.

Figure  shows the spatial variations in snow surface temperature, observed by Landsat 8 (left) and simulated by the RoughSEB model (right). The variations are well represented by the model, with many similarities at all the scales across the domain. The small-scale variations are better resolved by the model as the spatial resolution is significantly higher (10 vs. 30 m for the satellite). This is in particular true in the northern area of the domain, which features a series of small valleys, showing a larger temperature gradient in the simulation. The model is slightly colder in the coldest areas (e.g. shadows in the southern area of the scene) as well as in the warmest areas around the FluxAlp station (green marker). As shown in Fig. b, the surface temperature does not differ significantly in the FluxAlp area.

Figure  (left) shows the bias and standard deviation of a pixel-to-pixel comparison between all the 20 satellite observations and the corresponding simulations. The latter are resampled to 30 m to match the spatial resolution of the Landsat 8 observations. Figure  (right) shows the correlation coefficient r as a function of the RMSE between simulations and remote sensing observations. The simulations are slightly colder in general, with a bias principally between -3 and 1 ∘C. The standard deviation of the differences varies mostly between 1 and 3 ∘C (2 and 4 ∘C for the RMSE). Some outliers are observed, and in particular the simulation that shows the highest differences (both standard deviation and RMSE) corresponds to an acquisition from late March. Such differences could be explained with an early onset of snowmelt (snow patches in the lowest areas) due to mild temperatures, a particular situation that breaks the assumptions in the model (e.g. 100 % snow cover). The shallow snowpack in early winter (probable patches of bare soil) can lead to a similar situation, where the bare soil temperature would be certainly different than that of snow-covered terrain. This could explain the lowest correlation value of the dataset, which corresponds to an acquisition from early December. Nevertheless, apart from these two cases, considering all acquisitions, these differences do not seem to be clearly related to the time of the year (shown as colour in Fig. 8), so strong conclusions cannot be drawn.

These results show the performance of the RoughSEB model to simulate the snow surface temperature in complex terrain within a reasonable accuracy. The temporal and spatial variations in Ts are also well represented in the study area. To understand these variations, the role of the topographic effects is addressed in the following section.

In order to quantify the relative importance of the topographic effects, we run a series of simulations where every effect considered in this work is disabled at a time. The importance of applying an elevation-corrected downward LW flux instead of considering a uniform one is also quantified. Figure  shows the impact on the surface temperature distribution across the area on 18 February 2018. The scatter plots show the modelled Ts for every pixel in the domain as a function of the Ts from the reference simulation (REF), where all the effects are included. The histogram plots show the distribution of all the pixels and, in addition, the reference simulation (black line) – including all the effects – and Landsat 8 observations (red).

To extend these results to all the dates, Fig.  displays summary statistics of the difference between the simulations with a disabled topographic effect and the reference simulation. The left panel presents the mean difference between the simulation without the effect and the reference simulations (for each effect), while the standard deviation of the differences (right panel) shows how both simulations agree in terms of spatial variations. A value close to zero means that the effect is negligible in terms of average and variations, respectively.

When no topography is taken into account (i.e. a perfectly flat surface instead of the actual topography), the snow surface temperature is uniform (-5.9 ∘C) across the scene. This value overestimates the mean temperature of the reference simulation (-7.2 ∘C), showing that not only the spatial variations in temperature are not represented (r value ≈0), but even on average a simulation with flat terrain is not equivalent to the mean temperature of the area with topography. This simulation highlights the considerable effect of the topography on the surface temperature and the importance to take it into account even for large-scale simulations. Considering all the 20 dates, neglecting the topography results in an overall overestimation of 1.3 ∘C (median value), and the standard variations with respect to the reference simulation are high, with a median value of 3.2 ∘C and a maximum of 6 ∘C.

The simulation with single-scattering only in the SW (only the first bounce of the photons is considered by RSRT; the absorption enhancement is neglected) shows very small differences with respect to the reference simulation. It is only slightly colder, in particular in the coldest pixels. This is mainly due to neglecting the illumination in the shadowed (and cold) areas coming from slopes facing towards cold areas. Nevertheless, the impact is not significant, the mean difference being barely different from zero (median of -0.2 ∘C, standard variations of 0.2 ∘C). The smallest impact is observed in early winter, which could be explained by a dependence on the solar zenith angle and on how the topography modulates the received solar irradiance. Overall, this result means that, at least in our study area, the absorption enhancement caused by multiple bouncing is almost negligible.

When neglecting the spectral dependence of snow albedo and thus calculating SWnet directly from the broadband albedo (≈0.87 on 18 February 2018), the simulated surface temperature is slightly warmer than the reference, with overall differences of 0.5 ∘C (median of the means) and of 0.7 ∘C (median of standard deviations), with a maximum beyond 1.5 ∘C. This shows the importance of taking into account this effect involving the coupling between spectral dependence of snow albedo and topography.

The effect of the thermal emission by surrounding terrain in the LW is obtained by estimating the surface temperature as if the terrain were flat (first step as detailed in Sect. ). For the selected date in Fig.  the peak of the distribution is less marked and widened in the range of -5 to -8 ∘C, and Ts is systematically underestimated when this approximation is applied. The difference in the warmest areas of the domain (>-5 ∘C) is of -0.6 ∘C. In the coldest areas (<-12 ∘C), the underestimation is of -1.4 ∘C because direct radiation is absent, and the radiation budget is dominated by diffuse and weak illumination. The thermal emission by surrounding faces warms these cold areas as a function of their sky-view factor. The mean difference is -0.7 ∘C (standard variations of 0.6 ∘C) when considering all the simulations.

Neglecting the altitudinal variations in the downwelling LW flux over the study area has a limited impact on Ts. Slight differences are mainly concentrated in the range of -3 to -8 ∘C and also in the coldest areas, where the Ts is overestimated by almost 0.6 ∘C. Parts of these zones are at the highest altitudes of the study area, and without the correction they receive more downwelling LW flux (up to ≈15–20 Wm-2), leading to warmer surface temperature. Overall, neglecting the altitudinal variations barely overestimates the estimation of Ts by 0.2 ∘C, with errors that are not significant (median value of 0.3 ∘C).

With respect to the altitudinal variations in air temperature (lapse rate effect), the distribution shape squeezes and even becomes bimodal, with two marked peaks at -5 and -10 ∘C when the lapse rate is neglected (Fig. ). The differences to the reference simulation are significant when considering all the dates, with a median value of 0.9 ∘C and a median standard deviation of 1.3 ∘C. Introducing the lapse rate effect tends to warm the air in the lower parts of the domain (usually the warmest) and the opposite on the highest and coldest facets. Since the FluxAlp measurement station (where the reference air temperature is taken) is in the lower range of altitudes of the study area, the overall impact of neglecting the lapse rate effect is an overestimation (0.9 ∘C). This result is specific to the position of the station with respect to the altitudinal distribution, and using a different reference air temperature would change this result. In contrast, the standard variations are also significant, and this is not specific to our setting. It effectively shows that neglecting the altitudinal variations in air temperature results in an overall significant error of 1.3 ∘C (median) in surface temperature over the study area. The correlation coefficient is the lowest, with a median value of 0.921 considering all the simulations.

These results give the relative importance of the topographic effects investigated here. Neglecting the topography (i.e. assuming a flat surface) is as expected the most important source of error when simulating snow surface temperature. Neglecting the altitudinal variations in air temperature is the second effect in terms of importance. It is followed by the thermal emission by surrounding terrain in the LW and the spectral dependence of snow albedo, the latter being slightly less important. Finally, the absorption enhancement caused by multiple bouncing is almost negligible, as are the altitudinal variations in downwelling LW flux.