Abstract
ABSTRACTThermodynamics of a seasonal supraglacial lake were examined based on field data from three summers. At maximum, the lake body consisted of an upper layer with thin ice on top, and a lower layer with slush, hard ice and sediment at the bottom. Sublimation from the upper ice surface averaged to 0.7 mm d−1, and melting in the ice interior averaged to 9.1 mm d−1 during summer. Albedo was on average 0.6 and light attenuation coefficient was ~1 m−1. Averaged over December and January, and over 3 different years, we found that the net solar heating was 137 W m−2, while the losses averaged to 62 W m−2 for the longwave radiation, 16 W m−2 for the sensible heat flux, 24 W m−2 for the latent heat flux and 3 W m−2 for the bottom flux. The depth scale is determined by the light attenuation distance and thermal diffusion coefficient, and the net liquid water volume ranged from 0.5 to 1.0 m in different years. The potential winter growth is more than summer melting, and thus the lake freezes up completely in winter in the present climate.
Highlights
Supraglacial lakes are found in the surface layer of ice sheets and glaciers
The mixture is described by its porosity ν = ν(x, y, z; t), which equals the relative volume of liquid water
The structure can be idealized as a two-layer system: upper layer of liquid water and slush, and a lower layer of solid ice and slush sub-layers (Leppäranta and others, 2013b)
Summary
Supraglacial lakes are found in the surface layer of ice sheets and glaciers. They can be classified into ‘warm-environment’ lakes where the surface is at the melting stage, and ‘cold- environment lakes’ where the surface temperature is below the melting point. This research focuses on the largely overlooked cold-environment supraglacial lakes using data gathered in western Dronning Maud Land, Antarctica. These cold-environment supraglacial lakes behave quite differently from warm-environment supraglacial lakes, which are widespread in Greenland (Liang and others, 2012). In the Dronning Maud Land, such blue-ice areas are typically found on the lee side of mountains. The mass balance of these lakes is simple, consisting of sublimation and compensating upwelling flow of ice
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