Analysis of IASI tropospheric O&amp;lt;sub&amp;gt;3&amp;lt;/sub&amp;gt; data over the Arctic during POLARCAT campaigns in 2008

M Pommier,G Ancellet,J.-D Paris,H Schlager,P Nédélec,P Bernath,T B Ryerson,A J Weinheimer,K S Law,J Hadji-Lazaro,F Ravetta,C Clerbaux,D Hurtmans,P.-F Coheur

doi:10.5194/acp-12-7371-2012

Abstract

Abstract. Ozone data retrieved in the Arctic region from infrared radiance spectra recorded by the Infrared Atmospheric Sounding Interferometer (IASI) on board the MetOp-A European satellite are presented. They are compared with in situ and lidar observations obtained during a series of aircraft measurement campaigns as part of the International Polar Year POLARCAT activities in spring and summer 2008. Different air masses were sampled during the campaigns including clean air, polluted plumes originating from anthropogenic sources, forest fire plumes from the three northern continents, and stratospheric-influenced air masses. The comparison between IASI O3 [0–8 km], [0–12 km] partial columns and profiles with collocated aircraft observations is achieved by taking into account the different sensitivity and geometry of the sounding instruments. A detailed analysis is provided and the agreement is discussed in terms of vertical sensitivity and surface properties at the location of the observations. Overall, IASI O3 profiles are found to be in relatively good agreement with smoothed in situ and lidar profiles in the free troposphere with differences of less than 40% (25% over sea for both seasons) and 10%, respectively. The correlation between IASI O3 retrieved partial columns and the smoothed aircraft partial columns is good with DC-8 in situ data in spring over North America (r = 0.68), and over Greenland with ATR-42 lidar measurements in summer (r = 0.67). Correlations with other data are less significant highlighting the difficulty of IASI to capture precisely the O3 variability in the Arctic upper troposphere and lower stratosphere (UTLS). This is particularly noted in comparison with the [0–12 km] partial columns. The IASI [0–8 km] partial columns display a low negative bias (by less than 26% over snow) compared to columns derived from in situ measurements. Despite the relatively high biases of the IASI retrievals in the Arctic UTLS, our analysis shows that IASI can be used to identify, using O3 / CO ratios, stratospheric intrusions.

Highlights

The Arctic is a region that is very sensitive to changes in atmospheric dynamics and composition, and is strongly affected by climate change
This paper compares tropospheric O3 concentrations retrieved from the Infrared Atmospheric Sounding Interferometer (IASI) satellite-borne instrument using the FORLI-O3 algorithm with aircraft measurements obtained as part of POLARCAT in spring and summer 2008
Data were collected in different parts of the Arctic, for air masses influenced by anthropogenic emissions, boreal forest fires over Siberia and Canada as well as air masses in the upper troposphere and the stratosphere

Summary

Introduction

The Arctic is a region that is very sensitive to changes in atmospheric dynamics and composition, and is strongly affected by climate change. This area receives pollution from the Northern Hemisphere continents leading. Tropospheric O3 plays an important role in the chemical processes occurring in the atmosphere and has a major impact on the climate. It is produced by photochemical oxidation of carbon monoxide (CO), methane (CH4) and non-methane volatile organic compounds (NMVOCs) in the presence of nitrogen oxides NOx (NO + NO2). Large-scale deposition occurs in summer and autumn over Siberian forests (Engvall Stjernberg et al, 2012)

Objectives

Methods

Results

Conclusion