Abstract
Current sea-level rise partly stems from increased surface melting and meltwater runoff from the Greenland ice sheet. Multi-year snow, also known as firn, covers about 80% of the ice sheet and retains part of the surface meltwater. Since the firn cold content integrates its physical and thermal characteristics, it is a valuable tool for determining the meltwater-retention potential of firn. We use gap-filled climatological data from nine automatic weather stations in the ice-sheet accumulation area to drive a surface-energy-budget and firn model, validated against firn density and temperature observations, over the 1998-2017 period. Our results show a stable top 20 m firn cold content (CC20) at most sites. Only at the lower-elevation Dye-2 site did CC20 decrease, by 24% in 2012, before recovering to its original value by 2017. Heat conduction towards the surface is the main process feeding CC20 at all nine sites, while CC20 reduction occurs through low-cold-content fresh-snow addition at the surface during snowfall and latent-heat release when meltwater refreezes. Our simulations suggest that firn densification, while reducing pore space for meltwater retention, increases the firn cold content, enhances near-surface meltwater refreezing and potentially sets favourable conditions for ice-slab formation.
Original language | English |
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Pages (from-to) | 591-602 |
Number of pages | 12 |
Journal | Journal of Glaciology |
Volume | 66 |
Issue number | 258 |
DOIs | |
Publication status | Published - Aug 2020 |
Keywords
- Accumulation area
- Greenland ice sheet
- Meltwater retention
- Polar firn
- Snow and firn processes
- Surface energy balance
- Surface mass balance
- Surface melt
Programme Area
- Programme Area 5: Nature and Climate