Cracks in Arctic sea ice turn low clouds on and off
- Date:
- January 10, 2020
- Source:
- University of Utah
- Summary:
- The prevailing view has been that more leads are associated with more low-level clouds during winter. But an atmospheric scientists noticed something strange in their study of these leads: when lead occurrence was greater, there were fewer, not more clouds.
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In the wintertime Arctic, cracks in the ice called "leads" expose the warm ocean directly to the cold air, with some leads only a few meters wide and some kilometers wide. They play a critical role in the Arctic surface energy balance. If we want to know how much the ice is going to grow in winter, we need to understand the impacts of leads.
The extreme contrast in temperature between the warm ocean and the cold air creates a flow of heat and moisture from the ocean to the atmosphere. This flow provides a lead with its own weather system which creates low-level clouds. The prevailing view has been that more leads are associated with more low-level clouds during winter. But University of Utah atmospheric scientists noticed something strange in their study of these leads: when lead occurrence was greater, there were fewer, not more clouds.
In a paper published in Nature Communications, they explain why: wintertime leads rapidly freeze after opening, so most leads have newly frozen ice that shuts off the moisture supply but only some of the heat flow from the ocean, thus causing any low-level clouds to dissipate and accelerating the freezing of sea ice compared to unfrozen leads. Understanding this dynamic, the authors say, will help more accurately represent the impact of winter-time leads on low-level clouds and on the surface energy budget in the Arctic -- especially as the Arctic sea ice is declining.
Story Source:
Materials provided by University of Utah. Note: Content may be edited for style and length.
Journal Reference:
- Xia Li, Steven K. Krueger, Courtenay Strong, Gerald G. Mace, Sally Benson. Midwinter Arctic leads form and dissipate low clouds. Nature Communications, 2020; 11 (1) DOI: 10.1038/s41467-019-14074-5
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