Abstract
Supra-glacial material, including light-absorbing impurities (LAI) such as mineral dust of crustal and soil origin, black carbon, algae and cryoconite, reduce the reflectance of snow and glacier ice. The reduction depends on the amount of LAI and their physical and chemical properties, which vary spatially and temporally. Spectral reflectance data and snow and ice samples, containing LAI, were collected in the ablation zone of the Djankuat Glacier, Central Caucasus, Russia. The spectra of the samples containing mineral dust transported from deserts were characterized by negative visible near-infrared gradients and were different from the spectra of clean aged snow and exposed glacier ice and from the samples containing mineral dust produced locally. Geochemical and mineralogical analysis using X-ray diffraction and X-ray fluorescence spectrometry showed that samples containing desert dust were characterised by a high proportion of clay materials and such minerals as smectites, illite–smectites and palygorskite and by a smaller size of mineral particles. They were enriched in chromium, zinc and vanadium. The latter served as an indicator of dust transport over or origin from the oil-producing regions of the Middle East. There was a strong negative correlation between the amount of organic matter and mineral dust in the collected samples and the albedo of surfaces from which the samples were collected. The results suggested that organic matter reduced albedo more efficiently than mineral dust. The study highlighted the importance of supra-glacial material in changing the surface reflectivity of snow and glaciers in the Caucasus region.
Highlights
Mountain glaciers and high-elevation snow pack are important components of water balance in many regions worldwide
light-absorbing impurities (LAI) generate direct positive at-surface radiative forcing (RF) increasing melt [4] and evoke a positive feedback whereby higher melt rates lead to an earlier loss of snow cover and exposure of the darker firn and bare ice surfaces, which absorb more energy resulting in further loss of snow and ice [5,6,7]
Cluster 2 was dominated by samples collected from the aged snow and ice surfaces with the presence of dust and other LAI
Summary
Mountain glaciers and high-elevation snow pack are important components of water balance in many regions worldwide. Changes in the albedo of snow and glacier ice are an important control over snow and glacier melt alongside air temperature. Albedo is controlled by several factors including the size of snow grains, water content of snow and amount and composition of light-absorbing impurities (LAI) deposited on snow and ice. LAI generate direct positive at-surface radiative forcing (RF) increasing melt [4] and evoke a positive feedback whereby higher melt rates lead to an earlier loss of snow cover and exposure of the darker firn and bare ice surfaces, which absorb more energy resulting in further loss of snow and ice [5,6,7]. The latter is derived either from crustal materials or from soils and is produced locally or/and transported from remote regions, predominantly from deserts [15,16]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
