Abstract. In August 2018, the first Doppler wind lidar in space called Atmospheric Laser Doppler Instrument (ALADIN) was launched on board the satellite Aeolus by the European Space Agency (ESA).
Aeolus measures profiles of one horizontal wind component (i.e., mainly the west–east direction) in the troposphere and lower stratosphere on a global basis. Furthermore, profiles of aerosol and cloud properties can be retrieved via the high spectral resolution lidar (HSRL) technique.
The Aeolus mission is supposed to improve the quality of weather forecasts and the understanding of atmospheric processes. We used the opportunity to perform a unique validation of the wind products of Aeolus by utilizing the RV Polarstern cruise PS116 from Bremerhaven to Cape Town in November/December 2018.
Due to concerted course modifications, six direct intersections with the Aeolus ground track could be achieved in the Atlantic Ocean west of the African continent.
For the validation of the Aeolus wind products, we launched additional radiosondes and used the EARLINET/ACTRIS lidar PollyXT for atmospheric scene analysis.
The six analyzed cases prove that Aeolus is able to measure horizontal wind speeds in the nearly west–east direction.
Good agreements with the radiosonde observations could be achieved for both Aeolus wind products – the winds observed in clean atmospheric regions called Rayleigh winds and the winds obtained in cloud layers called Mie winds (according to the responsible scattering regime).
Systematic and statistical errors of the Rayleigh winds were less than 1.5 and 3.3 m s−1, respectively, when compared to radiosonde values averaged to the vertical resolution of Aeolus. For the Mie winds, a systematic and random error of about 1 m s−1 was obtained from the six comparisons in different climate zones.
However, it is also shown that the coarse vertical resolution of 2 km in the upper troposphere, which was set in this early mission phase 2 months after launch, led to an underestimation of the maximum wind speed in the jet stream regions. In summary, promising first results of the first wind lidar space mission are shown and prove the concept of Aeolus for global wind observations.
Abstract. A shipborne Sun–sky–lunar photometer of type CE318-T was
tested during two trans-Atlantic cruises aboard the German research vessel
Polarstern from 54∘ N to 54∘ S in May/June and December 2018. The
continuous observations of the motion-stabilized shipborne CE318-T enabled
the first-time observation of a full diurnal cycle of aerosol optical depth
(AOD) and column-mean Ångström coefficient of a mixed dust–smoke
episode. The latitudinal distribution of the AOD from the shipborne CE318-T,
Raman lidar and MICROTOPS II shows the same trend with highest values in the
dust belt from 0 to 20∘ N and overall low values in
the Southern Hemisphere. The linear-regression coefficients of determination
between MICROTOPS II and the CE318-T were 0.988, 0.987, 0.994 and 0.994 for
AODs at 380, 440, 500 and 870 nm and 0.896 for the Ångström exponent
at 440–870 nm. The root-mean-squared differences of AOD at 380, 440, 500 and
870 nm were 0.015, 0.013, 0.010 and 0.009, respectively.
Variations in the total solar irradiance measured by the active cavity radiometer irradiance monitor (ACRIM) on SMM have been correlated with measures of magnetic activity on the solar disk. Quantitative indices of magnetic activity were derived from ground-based, full-disk, photometric images of the Sun at red (6723 •) and violet (3934-• K line) wavelengths. The red images have been obtained on a daily basis at the San Fernando Observatory since 1985, and the K line images since 1988. Sunspot irradiance deficits are calculated directly from the red images while proxy measures of facular irradiance excesses are derived from the K line images. The images analyzed here were made during 21 days between June 20 and July 14, 1988, a period centered on the disk passage of a large sunspot group. The best two-parameter multiple correlation coefficient between the ACRIM data and the photometric data is R 2 = 0.97 (21 data points, 18 degrees of freedom). The zero point So = 1367.27 W m -2 agrees well with the solar irradiance measured by ACRIM/SMM during the 1986 activity minimum; the residual standard deviation was 0.13 W m -2 (about 100 ppm). The multiple correlations were extended to include measures of the irradiance contribution of "network" magnetic fields, unassociated with active regions. NOAA 9 spacecraft observations of UV Mg II lines at 2800 • gave R 2 = 0.99 (17 degrees of freedom) with So = 1366.68 + 0.08 W m -2. The index of 10.7-cm microwave flux gave R 2 = 0.98, with So = 1366.43 + 0.11 W m -2. We can thus model short-term irradiance changes to within 100 ppm relative precision from ground-based data.
On 22nd August 2018, the European Space Agency (ESA) launched the first direct detection Doppler wind lidar into space. Operating at 355 nm and acquiring signals with a dual channel receiver, it allows wind observations in clear air and particle-laden regions of the atmosphere. Furthermore, particle optical properties can be obtained using the High Spectral Resolution Technique Lidar (HSRL) technique. Measuring with 87 km horizontal and 0.25-2 km vertical resolution between ground and up to 30 km in the stratosphere, the global coverage of Aeolus observations shall fill gaps in the global observing system and thus help improving numerical weather prediction. Within this contribution, first results from the German initiative for experimental Aeolus validation are presented and discussed. Ground-based wind and aerosol measurements from tropospheric radar wind profilers, Doppler wind lidars, radiosondes, aerosol lidars and cloud radars are utilized for that purpose.
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