Stratospheric ozone loss over the Eurasian continent induced by the polar vortex shift

Jiankai Zhang,Patrick Jöckel,Fiona M O’Connor,Sandip Dhomse,David A Plummer,Alexander T Archibald,Wuhu Feng,Yuanyuan Han,Olaf Morgenstern,Douglas E Kinnison ,Makoto Deushi,Slimane Bekki,Wenshou Tian,Martyn P Chipperfield,Eugene Rozanov,N L Abraham ,Martine Michou,Daniele Visioni,Seok‐Woo Son ,Fei Xie,Neal Butchart,Oliver Kirner ,Wuke Wang,Laura E Revell,Giovanni Pitari,Guang Zeng

doi:10.1038/s41467-017-02565-2

Abstract

The Montreal Protocol has succeeded in limiting major ozone-depleting substance emissions, and consequently stratospheric ozone concentrations are expected to recover this century. However, there is a large uncertainty in the rate of regional ozone recovery in the Northern Hemisphere. Here we identify a Eurasia-North America dipole mode in the total column ozone over the Northern Hemisphere, showing negative and positive total column ozone anomaly centres over Eurasia and North America, respectively. The positive trend of this mode explains an enhanced total column ozone decline over the Eurasian continent in the past three decades, which is closely related to the polar vortex shift towards Eurasia. Multiple chemistry-climate-model simulations indicate that the positive Eurasia-North America dipole trend in late winter is likely to continue in the near future. Our findings suggest that the anticipated ozone recovery in late winter will be sensitive not only to the ozone-depleting substance decline but also to the polar vortex changes, and could be substantially delayed in some regions of the Northern Hemisphere extratropics.

Highlights

The Montreal Protocol has succeeded in limiting major ozone-depleting substance emissions, and stratospheric ozone concentrations are expected to recover this century
The present study addresses this issue by analysing observed total column ozone (TCO) with a chemical transport model (SLIMCAT39, see details in Methods section and Supplementary Fig. 1) and chemistry-climate model (CCM) simulations
Our results reveal that the polar vortex shift towards the Eurasian continent has significantly enhanced the February TCO loss over this continent in the past three decades; this phenomenon may continue in the coming decades

Summary

Introduction

The Montreal Protocol has succeeded in limiting major ozone-depleting substance emissions, and stratospheric ozone concentrations are expected to recover this century. Stratospheric ozone protects life on Earth by strongly absorbing harmful solar ultraviolet (UV) radiation[1,2,3] It plays an important role in modulating the global climate system by partly controlling large-scale atmospheric circulations via its radiative impact and radiative-chemical-dynamical feedbacks, which are seen in both the Southern Hemisphere[4,5,6,7,8] and the Northern Hemisphere[9,10,11,12]. Recent studies have speculated that the future evolution of Northern Hemisphere stratospheric ozone may be more driven by changes in the strength of Arctic polar vortex than by chemical forcings (i.e., decreasing ODS levels from the continuing implementation of Montreal Protocol)[26,27,28]. Our results reveal that the polar vortex shift towards the Eurasian continent has significantly enhanced the February TCO loss over this continent in the past three decades; this phenomenon may continue in the coming decades

Methods

Results

Conclusion