An Unprecedented Arctic Ozone Depletion Event During Spring 2020 and Its Impacts Across Europe

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Authors

PETKOV Boyan H. VITALE Vito PIERO Di Carlo DROFA Oxana MASTRANGELO Daniele SMEDLEY Andrew R. D. DIEMOZ Henri SIANI Anna Maria FOUNTOULAKIS Ilias WEBB Ann R. BAIS Alkiviadis KIFT Richard RIMMER John CASALE Giuseppe Rocco HANSEN Georg H. SVENDBY Tove PAZMINO Andrea WERNER Rolf ATANASSOV Atanas M. LÁSKA Kamil DE BACKER Hugo MANGOLD Alexander KOEHLER Ulf VELAZCO Voltaire A. STUEBI Rene SOLOMATNIKOVA Anna PAVLOVA Kseniya SOBOLEWSKI Piotr S. JOHNSEN Bjorn GOUTAIL Florence MISAGA Oliver ARUFFO Eleonora METELKA Ladislav TOTH Zoltan FEKETE Denes ACULININ Alexandr A. LUPI Angelo MAZZOLA Mauro ZARDI Federico

Year of publication 2023
Type Article in Periodical
Magazine / Source Journal of Geophysical Research: Atmospheres
MU Faculty or unit

Faculty of Science

Citation
web https://doi.org/10.1029/2022JD037581
Doi http://dx.doi.org/10.1029/2022JD037581
Keywords Arctic ozone depletion; ozone column; Arctic vortex
Description The response of the ozone column across Europe to the extreme 2020 Arctic ozone depletion was examined by analyzing ground-based observations at 38 European stations. The ozone decrease at the northernmost site, Ny-Alesund (79°N) was about 43% with respect to a climatology of more than 30 years. The magnitude of the decrease declined by about 0.7% deg-1 moving south to reach nearly 15% at 40°N. In addition, it was found that the variations of the ozone column at each of the selected stations in March-May were similar to those observed at Ny-Alesund but with a delay increasing to about 20 days at mid-latitudes with a gradient of approximately 0.5 days deg-1. The distributions of reconstructed ozone column anomalies over a sector covering a large European area show decreasing ozone that started from the north at the beginning of April 2020 and spread south. Such behavior was shown to be similar to that observed after the Arctic ozone depletion in 2011. Stratospheric dynamical patterns in March–May 2011 and during 2020 suggested that the migration of ozone-poor air masses from polar areas to the south after the vortex breakup caused the observed ozone responses. A brief survey of the ozone mass mixing ratios at three stratospheric levels showed the exceptional strength of the 2020 episode. Despite the stronger and longer-lasting Arctic ozone loss in 2020, the analysis in this work indicates a similar ozone response at latitudes below 50°N to both 2011 and 2020 phenomena.
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