Detection of ozone recovery in the Arctic from ground-based measurements

Jonas, Caroline; Vigouroux, Corinne; Langerock, Bavo; Björklund, Robin; Boynard, Anne; Carlund, Thomas; Mazière, Martine De; Effertz, Peter; Errera, Quentin; Frey, Matthias M.; Granville, José; Hannigan, James W.; Keppens, Arno; Jepsen, Nis; Kivi, Rigel; Lyall, Norrie; Palm, Mathias; Prignon, Maxime; Sofieva, Viktoria F.; Strong, Kimberly; Svendby, Tove; Tarasick, David; Thölix, Laura; Malderen, Roeland Van; Virolainen, Yana; Löwis, Sibylle von; Zhao, Xiaoyi

Publication details

Journal: Atmospheric Chemistry and Physics (ACP), vol. 26, 8089–8124, June 11th 2026

Doi: doi.org/10.5194/acp-26-8089-2026
Arkiv: hdl.handle.net/11250/5529465
Archive: nva.sikt.no/registration/019ed573478a-6573d60b-41c0-488e-8d88-67855ae45b1a

Summary:
Contrary to the Antarctic, where ozone recovery has been observed for about a decade, the detection of positive ozone trends in the Arctic remains challenging due to higher natural variability of ozone in that region. Using a merging of long-term ozone data from Fourier transform infrared spectrometers, ozonesondes, and Dobson and Brewer spectrophotometers, we present regional long-term trends (2000–2024) for total, stratospheric and tropospheric ozone. First, ground-based measurements are cross-compared to two satellite data sets (MEGRIDOP and IASI-CDR). This enables the detection of drifts in ground-based data sets we further exclude from our study. We then use a representativeness study based on CAMS re-analysis data to define regions for which representative trends with reduced uncertainties are obtained by combining data sets from different instruments and stations. Annual and seasonal trends are calculated using a multiple linear regression technique involving a set of proxies that represent physical processes influencing the natural ozone variability. Annual trends indicate increasing total ozone over the Arctic, and are statistically significant over Canada and Reykjavik (+2.1 % per decade) and North-West Europe (Harestua and Lerwick, +0.7 % per decade). Ozone recovery is also observed over Canada in the mid-stratosphere (+2.0 % per decade) and over the North Pole region (Canada and Ny-Ålesund) in the upper stratosphere (+2.1 % per decade to +3.8 % per decade). By analyzing the sensitivity of the ozone trends to the proxies, we observe a slow down of the expected ozone recovery, especially in the lower stratosphere, due to stratospheric cooling (−0.6 % per decade) and to the increase of volume of polar stratospheric clouds (−0.8 % per decade).