Structure of a shear‐line polar low

• Published in: Quarterly journal of the Royal Meteorological Society Vol. 143; no. 702; pp. 12 - 26
• Main Authors: Sergeev, D. E., Renfrew, I. A., Spengler, T., Dorling, S. R.
• Format: Journal Article
• Language: English
• Published: Chichester, UK John Wiley & Sons, Ltd 01.01.2017; Wiley Subscription Services, Inc
• Subjects: aircraft observations; CloudSat; Met Office Unified Model; Norwegian Sea; polar low; shear line; ANE, Norwegian Sea; PN, Arctic
• ISSN: 0035-9009; 1477-870X
• DOI: 10.1002/qj.2911

During March 2013 a series of polar lows originated in a high‐vorticity (>10−3 s−1) shear zone that was associated with a prolonged marine cold‐air outbreak over the Norwegian Sea. A detailed analysis of one shear‐line polar low at the leading edge of the outbreak is presented using comprehensive observations from a well‐instrumented aircraft, dropsondes, scatterometer and CloudSat data, and numerical modelling output from a convection‐resolving configuration of the Met Office Unified Model. The maximum low‐level wind gradient across the shear line was 25 m s−1 over 50 km. High winds to the north and west were within the cold air mass and were associated with large surface turbulent heat fluxes and convective clouds. Low wind speeds to the south and east of the shear line were associated with low heat fluxes and a clear ‘eye’ in the polar low. Shear‐line meso‐gamma‐scale instabilities merging into the polar low appeared important to its structure and development. The model captured the shear line and the polar low structure very well–in particular the strength of the horizontal shear and the mesoscale thermodynamic fields. The spatial structure of convective cloud bands around the polar low was simulated reasonably well, but the model significantly underestimated the liquid water content and height of the cloud layers compared to the observations. Shear‐line polar lows are relatively common, however this case is arguably the first to be examined with a wide range of in situ and remote observations allied with numerical model output. In late March 2013 maritime air masses over the Norwegian Sea were swept away by colder Arctic air, as highlighted by blue‐orange temperature field in the image. Following the green vectors of the wind field, one can see the dramatic wind shear at the forefront of the cold‐air outbreak, and the intense polar low that was spawned. Its beautiful cloud signature was captured by the MODIS instrument (true colour image provided by NEODAAS NERC Satellite Receiving Station, Dundee University). The article by Sergeev D. et al. describes the anatomy and evolution of this shear‐line polar low, blending unique airborne measurements with coincident CloudSat and scatterometer observations. Complementing the picture, the Met Office NWP model reproduced the structure and the convective processes within the polar low, as demonstrated by the 3D images of total cloud (white) and frozen (cyan) water.