Abstract
The timing of melt onset in the Arctic plays a key role in the evolution of sea ice throughout Spring, Summer and Autumn. A major catalyst of early melt onset is increased downwelling longwave radiation, associated with increased levels of moisture in the atmosphere. Determining the atmospheric moisture pathways that are tied to increased downwelling longwave radiation and melt onset is therefore of keen interest. We employed Self Organizing Maps (SOM) on the daily sea level pressure for the period 1979–2018 over the Arctic during the melt season (April–July) and identified distinct circulation patterns. Melt onset dates were mapped on to these SOM patterns. The dominant moisture transport to much of the Arctic is enabled by a broad low pressure region stretching over Siberia and a high pressure over northern North America and Greenland. This configuration, which is reminiscent of the North American-Eurasian Arctic dipole pattern, funnels moisture from lower latitudes and through the Bering and Chukchi Seas. Other leading patterns are variations of this which transport moisture from North America and the Atlantic to the Central Arctic and Canadian Arctic Archipelago. Our analysis further indicates that most of the early and late melt onset timings in the Arctic are strongly related to the strong and weak emergence of these preferred circulation patterns, respectively.
Highlights
Spring and summer in the Arctic are periods of great change and uncertainty
The master Self Organizing Maps (SOM) arranges sea level pressure (SLP) fields into a range of patterns that occur during the melt season (Fig. 3) with the strongest anomalies occurring on the outer edges of the SOM map
This study has identified dominant patterns of synoptic atmospheric circulation that transport moisture from lower latitudes into the Arctic initiating melt onset using a selforganizing map
Summary
Spring and summer in the Arctic are periods of great change and uncertainty. Warm weather and an increase in atmospheric moisture content produce changes to the snow and sea ice cover, drastically altering the energy budget of the Arctic, which in turn affects planetary atmospheric and oceanic circulation. Sea ice cover has an average decrease of 4% per decade (Cavalieri and Parkinson 2012) since the beginning of the satellite era, with the most pronounced decline occurring at the end of the melt season in September (Onarheim et al 2018; Stroeve and Notz 2018) This decrease, during summer months (June, July, August, and September) has led to an extension of the Arctic Ocean open water season by about a week each decade (Stroeve et al 2014). Open water shipping routes along the Northern Sea Route, over the North Pole, and through the Northwest Passage are expected to become navigable by the mid-twenty-first century, impacting environmental, strategic, economic, and governance for the Arctic region (Smith and Stephenson 2013) This increase in activity in the Arctic Ocean requires a better understanding of the mechanisms driving sea ice loss and a need to determine sources of predictability on synoptic and seasonal
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