Atmospheric Chemistry and Physics Discussions
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2003
10.5194/acpd-3-4393-2003
http://www.atmos-chem-phys-discuss.net/3/4393/2003/
http://www.atmos-chem-phys-discuss.net/3/4393/2003/acpd-3-4393-2003.html
http://www.atmos-chem-phys-discuss.net/3/4393/2003/acpd-3-4393-2003.pdf
4393
4410
2003-08-05
Stratospheric water vapour as tracer for vortex filamentation in the Arctic winter 2002/2003
M. Müller
R. Neuber
F. Fierli
A. Hauchecorne
H. Vömel
S. J. Oltmans
Alfred Wegener Institute for Polar and Marine Research, Potsdam, Germany
Istituto di Scienze dell’Atmosfera e del Clima, CNR, Rome, Italy
Service D’Aéronomie du CNRS, Verrières-le-Buisson, France
Cooperative Institute for Research in Environmental Sciences, University of Colorado, Boulder, Colorado, USA
Climate Monitoring and Diagnostics Laboratory, NOAA, Boulder, Colorado, USA
During winter 2002/2003, three balloon-borne frost point hygrometers measured high-resolution
profiles of stratospheric water vapour above Ny-Ålesund, Spitsbergen. All
measurements reveal a high H<sub>2</sub>O mixing ratio of about 7 ppmv above
24 km, thus differing significantly from the 5 ppmv that are commonly assumed for the calculation of polar
stratospheric cloud existence temperatures. The profiles obtained on 12 December 2002 and
on 17 January 2003 provide an insight into the vertical distribution of water vapour in the core
of the polar vortex.<br>
<br>
Unlike the earlier profiles, the water vapour sounding on 11 February 2003 detected the
vortex edge region in the lower part of the stratosphere. Here, a striking diminuition in
H<sub>2</sub>O mixing ratio stands out between 16 and 19 km. The according stratospheric temperatures
clarify that this dehydration can not be caused by the presence of polar stratospheric clouds or
earlier PSC particle sedimentation.<br>
<br>
On the same day, ozone observations by lidar indicate a large scale movement of the polar
vortex, while an ozone sonde measurement even shows laminae in the same altitude range as
in the water vapour profile. Tracer lamination in the vortex edge region is caused by
filamentation of the vortex. The link between the observed water vapour diminuition and
filaments in the vortex edge region is highlighted by results of the MIMOSA contour
advection model. In the altitude of interest, adjoined filaments of polar and mid-latitudinal air
can be identified above the Spitsbergen region. A vertical cross-section reveals that the water
vapour sonde has flown through polar air in the lowest part of the stratosphere. Where the low
water vapour mixing ratio was detected, the balloon passed through air from a mid-latitudinal
filament from about 425 to 445 K, before it finally entered the polar vortex above
450 K. The MIMOSA model results elucidate the correlation that on 11 February 2003 the frost point
hygrometer measured strongly variable water vapour concentrations as the sonde detected air
with different origins, respectively.<br>
<br>
Instead of being linked to dehydration due to PSC particle sedimentation, the local
diminuition in the stratospheric water vapour profile of 11 February 2003 has been found to
be caused by dynamical processes in the polar stratosphere.