Arctic Lower-Tropospheric Warm and Cold Extremes Horizontal and Vertical Transport, Diabatic Processes, and Linkage to Synoptic Circulation Features

The thermodynamic processes and synoptic circulation features driving lower-tropospheric temperature extremes in the high Arctic (>80°N) are investigated. Based on 10-day kinematic backward trajectories from the 5% most intense potential temperature anomalies, the contributions of horizontal and...

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Bibliographic Details
Published inJournal of climate Vol. 33; no. 3; pp. 993 - 1016
Main Author Papritz, Lukas
Format Journal Article
LanguageEnglish
Published Boston American Meteorological Society 01.02.2020
Subjects
Aerodynamics
Air masses
Air temperature
Anomalies
Anticyclones
Blocking anticyclones
Climate
Cold
Cold air outbreaks
Cyclones
Diabatic heating
Extreme cold
Heat
Heat exchange
Heat flux
Heat transfer
Heating
Polar vortex
Potential temperature
Radiative cooling
Storms
Subsidence
Summer
Temperature anomalies
Temperature extremes
Transport
Troposphere
Vertical advection
Warm air
Winter
Arctic region
Greenland
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Summary:The thermodynamic processes and synoptic circulation features driving lower-tropospheric temperature extremes in the high Arctic (>80°N) are investigated. Based on 10-day kinematic backward trajectories from the 5% most intense potential temperature anomalies, the contributions of horizontal and vertical transport, subsidence-induced warming, and diabatic processes to the generation of the Arctic temperature anomaly are quantified. Cold extremes are mainly the result of sustained radiative cooling due to a sheltering of the Arctic from meridional airmass exchanges. This is linked to a strengthening of the tropospheric polar vortex, a reduced frequency of high-latitude blocking, and in winter also a southward shift of the North Atlantic storm track. The temperature anomaly of 60% of wintertime extremely warm air masses (90% in summer) is due to transport from a potentially warmer region. Subsidence from the Arctic midtroposphere in blocking anticyclones is the most important warming process with the largest contribution in summer (70% of extremely warm air masses). In both seasons, poleward transport of already warm air masses contributes around 20% and is favored by a poleward shift of the North Atlantic storm track. Finally, about 40% of the air masses in winter are of an Arctic origin and experience diabatic heating by surface heat fluxes in marine cold air outbreaks. Our study emphasizes the importance of processes in the Arctic and the relevance of anomalous blocking—in winter in the Barents, Kara, and Laptev Seas and in summer in the high Arctic—for the formation of warm extremes.
ISSN:0894-8755
1520-0442
DOI:10.1175/jcli-d-19-0638.1