SCIAMACHY and GOME H2O total columns over Europe for 27 Jan 2003.
The smaller SCIAMACHY ground pixels are marked by boxes.
(Click to enlarge)
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SCIAMACHY and GOME H2O total columns over Europe for 27 Jan 2003. The smaller SCIAMACHY ground pixels are marked by boxes. (Click to enlarge) |
Although no clouds are considered in the reference atmospheric model,
the method of air mass correction provides the possibility to retrieve
meaningful H2O total columns also for partly cloudy scenes.
The size of the air mass correction factor can be used a criterium for
the quality of the H2O data product.
In the ideal case, i.e. if the atmospheric conditions used in the
model calculations match the real conditions, the air mass correction
factor should be 1.
In the presence of clouds, only the atmosphere above the
clouds can be probed by the instrument, so the effective amount of
both O2 and H2O seen by SCIAMACHY is smaller than the amount used in
the model calculations.
The air mass factor correction would then try to compensate for this.
In this case the correction factor would be smaller than 1.
If the air mass correction factor deviates too much from 1, this is an
indication that the conditions of the reference atmosphere differ to
much from reality.
In this case the retrieved H2O columns are considered to be
unrealistic.
In practice, it could be shown that data retrieved with air mass correction factors smaller than 0.8 are unreliable. Therefore, these data have been omitted from the following plots. In addition, measurements performed at high solar zenith angles (larger than 88 deg) and backscan pixels have been excluded.
All SCIAMACHY results presented here are based on preliminarily calibrated data and are thus also of preliminary nature.
The SCIAMACHY results have been compared with DMSP F14 SSM/I data provided by the Global Hydrology Research Center (GHRC) at the Global Hydrology and Climate Center, Huntsville, Alabama, and with assimilated global water vapour data provided by the European Centre for Medium-Range Weather Forecast (ECMWF).
Previous retrieval results (Noël et al., 2004a) using the AMC-DOAS algorithm
with SCIAMACHY data revealed systematically about 10% lower water vapour
columns derived from SCIAMACHY data in comparison with corresponding SSM/I data over ocean.
A similar offset was seen by the
WFM-DOAS method.
This offset could be essentially removed by using an updated instrument slit
function (see Noël et al., 2005).
Therefore, the AMC-DOAS water vapour columns presented here have not been scaled.
For the comparison with correlative measurements, all data have been gridded to 0.5 deg x 0.5 deg.
SCIAMACHY H2O total columns for 27 Jan 2003 (swath data)
(Click to enlarge) |
SSM/I H2O total columns for 27 Jan 2003, descending part only
(Click to enlarge) |
ECMWF H2O total columns for 27 Jan 2003
(Click to enlarge) |
Comparison between SCIAMACHY AMC-DOAS and SSM/I (descending) H2O total
columns for 27 Jan 2003; red line = 1:1 correlation;
r = linear Pearson's correlation coefficient
(Click to enlarge) |
Comparison between SCIAMACHY AMC-DOAS and ECMWF H2O total
columns for 27 Jan 2003; red line = 1:1 correlation;
r = linear Pearson's correlation coefficient
(Click to enlarge) |
The SCIAMACHY results agree within a scatter of about 0.5 g/cm2 with corresponding
SSM/I and ECMWF water vapour data.
This deviation includes contributions from the temporal and spatial variability
of water vapour.
In fact, the mean deviation between the SCIAMACHY and the correlative data sets
is much smaller: the SCIAMACHY total water vapour columns are typically about 0.2 g/cm2
lower than the SSM/I values and less than 0.1 g/cm2 lower than corresponding ECMWF data.
The SCIAMACHY water vapour results agree well with correlative data not only over ocean
but also over land, thus showing the capability of SCIAMACHY to derive water
vapour concentrations on the global scale.
If you are interested in more information on SCIAMACHY H2O, please contact Stefan Noël.
Note:
AMC-DOAS water vapour total columns are also available for the SCIAMACHY validation
master set.
Access to these data is provided via the
SCIAVALIG web site.
S. Noël, M. Buchwitz, H. Bovensmann, R. Hoogen, and J. P. Burrows, Atmospheric Water Vapor Amounts Retrieved from GOME Satellite Data , Geophys. Res. Lett., vol. 26(13), 1841-1844, 1999. (PS file, ca. 217 kB)
S. Noël, H. Bovensmann, J. P. Burrows, Water vapour retrieval from GOME data including cloudy scenes, Proc. ENVISAT/ERS Symposium, Gothenburg, 2000. (PDF file, ca.1.7 MB)
S. Noël, M. Buchwitz, H. Bovensmann, and J. P. Burrows, Retrieval of Total Water Vapour Column Amounts from GOME/ERS-2 Data, Adv. Space Res., 29(11), 1697-1702, 2002. (PS file, ca. 885 kB)
S. Noël, M. Buchwitz, J. P. Burrows, First retrieval of global water vapour column amounts from SCIAMACHY measurements, Atmos. Chem. Phys., 4, 111-125, 2004a. (PDF file at ACP web site, ca. 22.6 MB)
S. Noël, M. Buchwitz, H. Bovensmann, J. P. Burrows, SCIAMACHY water vapour retrieval using AMC-DOAS, to be published in Proc. ENVISAT Symposium, Salzburg, Austria, 6-10 September, 2004b. (PDF file, ca. 1.4 MB)
S. Noël, M. Buchwitz, J. P. Burrows, K.-U. Eichmann, H. Bovensmann,
Validation of SCIAMACHY AMC-DOAS water vapour columns,
Atmos. Chem. Phys. Discuss., 5, 1925-1942, 2005.
(link
to corresponding ACPD web site)
©2005