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Abstract
Abstract. In order to quantify the effects of absorbing contaminants on snow, a series of spectral reflectance measurements were conducted. Chimney soot, volcanic sand, and glaciogenic silt were deposited on a natural snow surface in a controlled way as a part of the Soot on Snow (SoS) campaign. The bidirectional reflectance factors of these soiled surfaces and untouched snow were measured using the Finnish Geodetic Institute's Field Goniospectropolariradiometer, FIGIFIGO. A remarkable feature is the fact that the absorbing contaminants on snow enhanced the metamorphism of snow under strong sunlight in our experiments. Immediately after deposition, the contaminated snow surface appeared darker than the natural snow in all viewing directions, but the absorbing particles sank deep into the snow in minutes. The nadir measurement remained the darkest, but at larger zenith angles, the surface of the contaminated snow changed back to almost as white as clean snow. Thus, for a ground observer the darkening caused by impurities can be completely invisible, overestimating the albedo, but a nadir-observing satellite sees the darkest points, underestimating the albedo. Through a reciprocity argument, we predict that at noon, the albedo perturbation should be lower than in the morning or afternoon. When sunlight stimulates sinking more than melting, the albedo should be higher in the afternoon than in the morning, and vice versa when melting dominates. However, differences in the hydrophobic properties, porosity, clumping, or size of the impurities may cause different results than observed in these measurements.
Highlights
Snowpacks and ice sheets around the globe play a crucial role in the Earth’s radiation budget
D d d ι d d d φ φ% ̈ ̈ ̈ ̈ddh0hhh paper we describe the measurements of the bidirectional reflectance factor (BRF) used to quantify the effects of different absorbing materials on snow using the Finnish Geodetic Institute’s Field Goniospectropolariradiometer, FIGIFIGO
The BRF is shown as a function of observer zenith and azimuth angles, integrated over the full measurement range weighed with a fixed solar spectrum; it gives a good overview of the reflected energy distribution
Summary
Snowpacks and ice sheets around the globe play a crucial role in the Earth’s radiation budget. The albedo of snow depends, among other factors, on its physical properties, such as, for example, snow grain size, shape, packing, topography, and snow thickness. It is usually significantly higher compared to that of other natural surfaces (Peltoniemi et al, 2015). With the rapidly-growing number of techniques for Earth observation, the accelerating shrinkage of snowpacks and glaciers over the past decades has been confirmed based on dedicated satellite and in situ measurements. In order to reliably interpret these observations and forecast further changes in snow cover, there is a need to increase existing knowledge on the processes affecting the state of snow.
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