Abstract
Abstract. Spatial variability in snowpack properties negatively impacts our capacity to make direct measurements of snow water equivalent (SWE) using satellites. A comprehensive data set of snow microstructure (94 profiles at 36 sites) and snow layer thickness (9000 vertical profiles across nine trenches) collected over two winters at Trail Valley Creek, NWT, Canada, was applied in synthetic radiative transfer experiments. This allowed for robust assessment of the impact of estimation accuracy of unknown snow microstructural characteristics on the viability of SWE retrievals. Depth hoar layer thickness varied over the shortest horizontal distances, controlled by subnivean vegetation and topography, while variability in total snowpack thickness approximated that of wind slab layers. Mean horizontal correlation lengths of layer thickness were less than a metre for all layers. Depth hoar was consistently ∼30 % of total depth, and with increasing total depth the proportion of wind slab increased at the expense of the decreasing surface snow layer. Distinct differences were evident between distributions of layer properties; a single median value represented density and specific surface area (SSA) of each layer well. Spatial variability in microstructure of depth hoar layers dominated SWE retrieval errors. A depth hoar SSA estimate of around 7 % under the median value was needed to accurately retrieve SWE. In shallow snowpacks <0.6 m, depth hoar SSA estimates of ±5 %–10 % around the optimal retrieval SSA allowed SWE retrievals within a tolerance of ±30 mm. Where snowpacks were deeper than ∼30 cm, accurate values of representative SSA for depth hoar became critical as retrieval errors were exceeded if the median depth hoar SSA was applied.
Highlights
Snow-covered non-glaciated Arctic terrestrial environments north of tree lines cover approximately 5.05 × 106 km2 (Walker et al, 2005)
Similar air temperatures were observed in both winters from October through November, but December through March in 2017–2018 was on average 9 ◦C warmer
During 2017–2018 there were three short (< 1 d) periods where mid-winter air temperatures increased above −5 ◦C and approached melting point
Summary
Snow-covered non-glaciated Arctic terrestrial environments north of tree lines cover approximately 5.05 × 106 km (Walker et al, 2005). Layering of snow, where distinct differences in snow properties exist between vertically adjacent strata (Fierz et al, 2009), is spatially heterogeneous in Arctic regions with a dense wind slab layer overlaying less-dense depth hoar (Benson and Sturm, 1993; see Fig. 1; Derksen et al, 2009). As depth hoar and wind slab have strongly diverging microwave scattering properties (Hall et al, 1991), the relative proportion of each strongly influences Ku-band radar backscatter (Yueh et al, 2009; King et al, 2015, 2018). Knowledge of how layers vary within Arctic snowpacks is critical to the assessment of uncertainty in radar-based retrievals of snow water equivalent (SWE) and forward models of snow radiative transfer. Rutter et al.: Effect of snow microstructure on SWE retrievals
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