Abstract
Abstract. It is well understood that the distribution and quantity of liquid water in snow is relevant for snow hydrology and avalanche forecasting, yet detecting and quantifying liquid water in snow remains a challenge from the micro- to the macro-scale. Using near-infrared (NIR) spectral reflectance measurements, previous case studies have demonstrated the capability to retrieve surface liquid water content (LWC) of wet snow by leveraging shifts in the complex refractive index between ice and water. However, different models to represent mixed-phase optical properties have been proposed, including (1) internally mixed ice and water spheres, (2) internally mixed water-coated ice spheres, and (3) externally mixed interstitial ice and water spheres. Here, from within a controlled laboratory environment, we determined the optimal mixed-phase optical property model for simulating wet snow reflectance using a combination of NIR hyperspectral imaging, radiative transfer simulations (Discrete Ordinate Radiative Transfer model, DISORT), and an independent dielectric LWC measurement (SLF Snow Sensor). Maps of LWC were produced by finding the lowest residual between measured reflectance and simulated reflectance in spectral libraries, generated for each model with varying LWC and grain size, and assessed against the in situ LWC sensor. Our results show that the externally mixed model performed the best, retrieving LWC with an uncertainty of ∼1 %, while the simultaneously retrieved grain size better represented wet snow relative to the established scaled band area method. Furthermore, the LWC retrieval method was demonstrated in the field by imaging a snowpit sidewall during melt conditions and mapping LWC distribution in unprecedented detail, allowing for visualization of pooling water and flow features.
Highlights
The distribution and quantity of liquid water within a snowpack, introduced by rain and/or melt, are relevant for multiple snow-related applications including snow hydrology, remote sensing, and avalanche forecasting
In terms of snow hydrology, water is an indicator of snow energy balance and snowmelt timing; the change in phase from ice to water indicates that the cold content of the snowpack is depleted and that energy balance inputs are contributing to melt (DeWalle and Rango, 2008)
Matrix flow is described as the semi-uniform vertical movement of water, while preferential flow is made up of concentrated water pathways that follow the path of least resistance that can extend deep into the snowpack, ahead of the matrix flow (Schneebeli, 1995)
Summary
The distribution and quantity of liquid water within a snowpack, introduced by rain and/or melt, are relevant for multiple snow-related applications including snow hydrology, remote sensing, and avalanche forecasting. Dye tracers provide a spatial visualization of water infiltration that has been used to study processes such as preferential flow (Schneebeli, 1995; Waldner et al, 2004) and capillary barriers (Avanzi et al, 2016). While these methods remain primarily a qualitative visualization technique, Williams et al (2010) quantified the threedimensional (3D) spatial distribution of meltwater within a 1 m3 snowpack using dye tracers and serial-section imaging. The 3D data were binarized into dry and wet categories to quantify flow features at the centimeter scale, but LWC is not obtainable using this method
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