Abstract
<strong class="journal-contentHeaderColor">Abstract.</strong> The retreat of Arctic sea ice is frequently considered to be a possible driver of changes in climate extremes in the Arctic and possibly down to mid-latitudes. However, it remains unclear how the atmosphere will respond to a near-total retreat of summer Arctic sea ice, a reality that might occur in the foreseeable future. This study explores this question by conducting sensitivity experiments with two global coupled climate models run at two different horizontal resolutions to investigate the change in temperature and precipitation extremes during summer over peripheral Arctic regions following a sudden reduction in summer Arctic sea ice cover. An increase in frequency and persistence of maximum surface air temperature is found in all peripheral Arctic regions during the summer, when sea ice loss occurs. For each <span class="inline-formula">1Ã10<sup>6</sup></span>âkm<span class="inline-formula"><sup>2</sup></span> of Arctic sea ice extent reduction, the absolute frequency of days exceeding the surface air temperature of the climatological 90th percentile increases by <span class="inline-formula">â¼</span>â4â% over the Svalbard area, and the duration of warm spells increases by <span class="inline-formula">â¼</span>â1âd per month over the same region. Furthermore, we find that the 10th percentile of surface daily air temperature increases more than the 90th percentile, leading to a weakened diurnal cycle of surface air temperature. Finally, an increase in extreme precipitation, which is less robust than the increase in extreme temperatures, is found in all regions in summer. These findings suggest that a sudden retreat of summer Arctic sea ice clearly impacts the extremes in maximum surface air temperature and precipitation over the peripheral Arctic regions with the largest influence over inhabited islands such as Svalbard or northern Canada. Nonetheless, even with a large sea ice reduction in regions close to the North Pole, the local precipitation response is relatively small compared to internal climate variability.
Highlights
Georges Lemaître Centre for Earth and Climate Research, Earth and Life Institute, Université catholique de Louvain, Louvain-la-Neuve, Belgium
The decrease in summer Arctic sea ice extent in percentile of the CTRL (PERT) compared to CTRL reaches 30% for the two ECMWF model configurations, and is largely localized in the eastern Arctic
The main reason for these discrepancies is a significant difference in mean sea ice state between the models, with a large mean sea ice thickness (Docquier et al, 2019) and relatively low ocean heat transport in the ECMWF configurations (Roberts et al, 2018; Docquier et al, 2019), which could lead to more sea ice in this model
Summary
Georges Lemaître Centre for Earth and Climate Research, Earth and Life Institute, Université catholique de Louvain, Louvain-la-Neuve, Belgium. The retreat of Arctic sea ice is frequently considered as a possible driver of changes in climate extremes in the Arctic and possibly down to mid-latitudes. It is unclear how the atmosphere will respond to a near-total retreat of summer. A reality that might occur in the foreseeable future This study explores this question by conducting sensitivity experiments with two global coupled climate models run at two different horizontal resolutions to investigate the change in temperature and precipitation extremes during summer over peripheral Arctic regions following a sudden reduction in summer.
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