This paper reports on an increase of ozone event observed over Kerguelen (49.4 degrees S, 70.3 degrees E) in relationship with large-scale isentropic transport. This is evidenced by ground-based observations (co-localised radiosonde and SAOZ experiments) together with satellite global observations (Aura/MLS) assimilated into MOCAGE, a Meteo-France model.
The study is based on the analyses of the first ozonesonde experiment never recorded at the Kerguelen site within the framework of a French campaign called ROCK that took place from April to August 2008.
Comparisons and interpretations of the observed event are supported by co-localised SAOZ observations, by global mapping of tracers (O-3, N2O and columns of O-3) from Aura/MLS and Aura/OMI experiments, and by model simulations of Ertel Potential Vorticity initialised by the ECMWF (European Centre for Medium-Range Weather Forecasts) data reanalyses.
Satellite and ground-based observational data revealed a consistent increase of ozone in the local stratosphere by mid-April 2008. Additionally, Ozone (O-3) and nitrous oxide (N2O) profiles obtained during January-May 2008 using the Microwave Limb Sounder (MLS) aboard the Aura satellite are assimilated into MOCAGE (MOdele de Chimie Atmospherique a Grande Echelle), a global three-dimensional chemistry transport model of Meteo-France. The assimilated total O-3 values are consistent with SAOZ ground observations (within +/- 5%), and isentropic distributions of O-3 match well with maps of advected potential vorticity (APV) derived from the MIMOSA model, a high-resolution advection transport model, and from the ECMWF reanalysis.
The event studied seems to be related to the isentropic transport of air masses that took place simultaneously in the lower-and middle-stratosphere, respectively from the polar region and from the tropics to the mid-latitudes.
In fact, the ozone increase observed by mid April 2008 resulted simultaneously: (1) from an equator-ward departure of polar air masses characterised with a high-ozone layer in the lower stratosphere (near the 475K isentropic level), and (2) from a reverse isentropic transport from the tropics to mid-and high-latitudes in the upper stratosphere (nearby the 700K level). The increase of ozone observed over Kerguelen from the 16-April ozonesonde profile is thus attributed to a concomitant isentropic transport of ozone in two stratospheric layers: the tropical air moving southward and reaching over Kerguelen in the upper stratosphere, and the polar air passing over the same area but in the lower stratosphere.

• 出版日期2011