Abstract

Abstract. Record breaking loss of ozone (O3) in the Arctic stratosphere has been reported in winter–spring 2010/2011. We examine in detail the composition and transformations occurring in the Arctic polar vortex using total column and vertical profile data products for O3, bromine oxide (BrO), nitrogen dioxide (NO2), chlorine dioxide (OClO), and polar stratospheric clouds (PSC) retrieved from measurements made by SCIAMACHY (Scanning Imaging Absorption SpectroMeter for Atmospheric CHartography) on-board Envisat (Environmental Satellite), as well as total column ozone amount, retrieved from the measurements of GOME-2 (Global Ozone Monitoring Experiment) on MetOp-A (Meteorological Experimental Satellite). Similarly we use the retrieved data from DOAS (Differential Optical Absorption Spectroscopy) measurements made in Ny-Ålesund (78.55° N, 11.55° E). A chemical transport model (CTM) has been used to relate and compare Arctic winter–spring conditions in 2011 with those in the previous year. In late winter–spring 2010/2011 the chemical ozone loss in the polar vortex derived from SCIAMACHY observations confirms findings reported elsewhere. More than 70% of O3 was depleted by halogen catalytic cycles between the 425 and 525 K isentropic surfaces, i.e. in the altitude range ~16–20 km. In contrast, during the same period in the previous winter 2009/2010, a typical warm Arctic winter, only slightly more than 20% depletion occurred below 20 km, while 40% of O3 was removed above the 575 K isentrope (~23 km). This loss above 575 K is explained by the catalytic destruction by NOx descending from the mesosphere. In both Arctic winters 2009/2010 and 2010/2011, calculated O3 losses from the CTM are in good agreement to our observations and other model studies. The mid-winter 2011 conditions, prior to the catalytic cycles being fully effective, are also investigated. Surprisingly, a significant loss of O3 around 60%, previously not discussed in detail, is observed in mid-January 2011 below 500 K (~19 km) and sustained for approximately 1 week. The low O3 region had an exceptionally large spatial extent. The situation was caused by two independently evolving tropopause elevations over the Asian continent. Induced adiabatic cooling of the stratosphere favoured the formation of PSC, increased the amount of active chlorine for a short time, and potentially contributed to higher polar ozone loss later in spring.

Highlights

  • Predicting the future levels of ozone (O3) above the Arctic and its loss during winter–spring is intrinsically challenging

  • It is of value to examine the causes of Arctic variability and their impact on polar ozone and its depletion, in order to improve our understanding of the chemical and dynamical control of stratospheric ozone in a changing climate. In this manuscript we investigate how the 2011 ozone loss evolved in the Arctic polar vortex by reporting correlative observations of ozone and related species (BrO, NO2, OClO), including polar stratospheric clouds (PSC), and probe our understanding of the vortex behaviour with a chemistry transport model

  • Depending on the specific dynamic situation of the Arctic polar vortex during winter and spring, the efficiency of the ClO/bromine oxide (BrO) cycle for ozone loss may dominate below the altitudes where nitrogen oxides (NOx = NO + NO2) catalytic cycles destroy most of the ozone (e.g. Salawitch et al, 2005; Kuttippurath et al, 2010)

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Summary

Introduction

Predicting the future levels of ozone (O3) above the Arctic and its loss during winter–spring is intrinsically challenging. It is of value to examine the causes of Arctic variability and their impact on polar ozone and its depletion, in order to improve our understanding of the chemical and dynamical control of stratospheric ozone in a changing climate In this manuscript we investigate how the 2011 ozone loss evolved in the Arctic polar vortex by reporting correlative observations of ozone and related species (BrO, NO2, OClO), including PSC, and probe our understanding of the vortex behaviour with a chemistry transport model. Depending on the specific dynamic situation of the Arctic polar vortex during winter and spring, the efficiency of the ClO/BrO cycle for ozone loss may dominate below the altitudes where nitrogen oxides (NOx = NO + NO2) catalytic cycles destroy most of the ozone

Methods
SCIAMACHY limb trace gas profiles
SCIAMACHY solar occultation
SCIAMACHY OClO and NO2 from nadir measurements
SCIAMACHY PSC detection description
Ground based measurements
Long-term total column ozone data set
Chemical ozone loss calculation
Chemistry transport model
Interannual variability
Stratospheric column ozone in March 2010 and 2011
SCIAMACHY limb measurements
Limb vortex averages
Inferred ozone loss
SCIAMACHY solar-occultation measurements
Modelled vortex averages
Modelled ozone loss
SCIAMACHY limb observations of PSC
Chlorine activation
Vertical columns of NO2 from SCIAMACHY nadir measurements
DOAS measurements at Ny-Ålesund
Low Arctic ozone in January 2011
Observations and meteorological situation
Comparison to a typical OMH condition
Modelling the January 2011 Arctic low ozone event
Implications for vortex-average ozone loss estimates
Findings
Conclusions

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