THE DEGLACIATION OF ICELAND: MODELLING THE MAXIMUM EXTENT AND SUBSEQUENT RAPID FLUCTUATIONS OF THE LATE WEICHSELIAN ICE-SHEET INTO THE HOLOCENE
The model successfully replicates the present-day ice distribution across Iceland with a temperature forcing of -2°C and a suite of sensitivity experiments are implemented to identify an optimal spin-up to the LGM. These experiments, integrated over 5,000 years using a scaled GRIP 18O record, testify that once the ice sheet has advanced beyond the coastline it is relatively independent of climate and largely controlled by relative sea level through ice-calving. Correspondence with field evidence indicates that the optimum LGM ice sheet extended significantly offshore with an area of 3.29 x 105 km2, but has a relatively low volume of 2.38 x 105 km3 yielding a mean ice thickness of 720 m with a net mass flux of ~900 km3 w.e. per year. The experiments highlight the central role played by basal thermodynamics in activating extensive areas of fast flow throughout the neovolcanic zone yielding a highly dynamic, low aspect ratio ice sheet with a maximum plateau elevation of 1,700 m breached throughout by numerous nunataks. The modelled ice sheet is subsequently forced into deglaciation using an optimally scaled GRIP record and is marked by a collapse of ~200,000 km3 of ice from offshore shelves at 17.5-16 ka, a period coinciding with the Heinrich-1 discharge event. A smaller collapse at 13.9 ka reflects the rapid withdrawal of ice from northern and western coast during the Bølling interstadial which is followed by the rapid cooling of the Younger Dryas which results in an independent icecap in the northwest and advances to topographic pinning points around the coast in most sectors.