CALIPSO First-Light Observations – All 3 Lidar Channels

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Presentation transcript:

CALIPSO First-Light Observations – All 3 Lidar Channels 9 June 2006 Desert dust Biomass smoke Cirrus 56.71 32.16 47.85 28.57 39.92 25.78 31.94 23.46 23.93 21.42 15.90 19.55 7.81 17.77 -0.23 16.05 -8.28 14.23 -16.31 12.56 -24.33 10.69 -32.32 8.64 -40.27 6.30 Altitude, km Fire locations in southern Africa from MODIS, 6/10/06 This figure shows calibrated Level 1 data from all three lidar channels: 532 nm total and perpendicular attenuated backscatter, and 1064 nm total attenuated backscatter (ie: not corrected for attenuation). The units of the color bar are /km/sr. The image shows a nighttime transect from northern Africa south to the Atlantic Ocean. High cirrus, probably produced by tropical convective systems, is seen in the center of the image. The backscatter signal from the cirrus is similar at both wavelengths, characteristic of the relatively large cirrus particles. The cirrus is also strongly depolarizing and produces a significant perpendicular (ie: cross-polarized) signal. To the south of the cirrus (right) is a smoke layer originating from biomass fires in southern Africa, which are widespread during this time of year (see MODIS fire map). Unlike the cirrus, this aerosol is weakly scattering at 1064 nm and non-depolarizing, which is the signature expected for smoke. The aerosol to the north of the cirrus (to the left) is primarily dust. Dust particles are also relatively large and depolarizing so produce strong 1064 nm and perpendicular signals. To the north of the dust is some other type of aerosol of unknown (at this time) origin. While the aerosol appears to be fairly uniform from roughly 20 N -40 N in the 532 nm total backscatter channel, it can be seen that the aerosol north of about 25 N is non-depolarizing and more weakly scattering at 1064 nm. This signature indicates the aerosol north of 25 N is composed of liquid droplets which are smaller than the dust particles found just to the south. This could be aerosol of urban origin.