Enhanced warming of seasonal cold extremes relative to the mean in the Northern Hemisphere extratropics
Cold extremes are anticipated to warm at a faster rate than both hot extremes and average temperatures for much of the Northern Hemisphere. The consequences of warming cold extremes can affect numerous sectors, including human health, tourism and various ecosystems that are sensitive to cold tempera...
| Main Authors: | , , , |
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| Format: | Text |
| Language: | English |
| Published: |
2019
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| Subjects: | |
| Online Access: | https://doi.org/10.5194/esd-2019-36 https://www.earth-syst-dynam-discuss.net/esd-2019-36/ |
| Summary: | Cold extremes are anticipated to warm at a faster rate than both hot extremes and average temperatures for much of the Northern Hemisphere. The consequences of warming cold extremes can affect numerous sectors, including human health, tourism and various ecosystems that are sensitive to cold temperatures. Using a selection of Global Climate Models, this paper explores the enhanced warming of seasonal cold extremes relative to seasonal mean temperatures in the Northern Hemisphere extratropics. The potentially driving physical mechanisms are investigated by assessing conditions on the day, or prior to, when the cold extreme occurs to understand how the different environmental fields are related. During winter months, North America, Europe and much of Eurasia show enhanced warming of cold extremes projected for the late 21 st century, compared to the mid-20 th century. This is shown to be largely driven by reductions in cold air temperature advection, suggested as a likely consequence of Arctic amplification. In spring and autumn, cold extremes are expected to warm faster than average temperatures for most of the Northern Hemisphere mid- to high-latitudes, particularly Alaska, northern Canada and northern Eurasia. In the shoulder seasons, projected decreases in snow cover and associated reductions in surface albedo are suggested as the largest contributor affecting the accelerated rates of warming in cold extremes. This study uses a novel approach to examine the day in which the extreme occurs to improve our understanding of the environmental conditions that contribute to the accelerated warming of cold extremes relative to mean temperatures. |
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