Potential impacts of air pollution aerosols on precipitation in Australia. The time-space exchangeability of satellite retrieved relations between cloud top temperature and particle effective radius. The scientific basis for these rendering schemes is provided, with examples for the applications. Clouds-aerosols-precipitation satellite analysis tool (CAPSAT) IM Lensky, D Rosenfeld. The main RGB compositions are (1) "Day Natural Colors", presenting vegetation in green, bare surface in brown, sea surface in black, water clouds as white, ice as magenta (2) "Day Microphysical", presenting cloud microstructure using the solar reflectance component of the 3.9 μm, visible and thermal IR channels (3) "Night Microphysical", also presenting clouds microstructure using the brightness temperature differences between 10.8 and 3.9 μm (4) "Day and Night", using only thermal channels for presenting surface and cloud properties, desert dust and volcanic emissions (5) "Air Mass", presenting mid and upper tropospheric features using thermal water vapor and ozone channels. The physical values are the solar reflectance in the solar channels and brightness temperature in the thermal channels. Cloud-Aerosol-Precipitation Interactions Based of Satellite Retrieved Vertical Profiles of Cloud Microstructure. The Clouds-Aerosols-Precipitation Satellite Analysis Tool (CAPSAT Lensky and Rosenfeld, 2008) uses all available VIS/IR channels to classify the imagery using lookup tables tailored to selected microphysical conditions. It has been known that AAC has significant potential to change the global radiation budget, namely plays an important role in elucidating climate change. A methodology for representing much of the physical information content of the METEOSAT Second Generation (MSG) geostationary satellite using red-green-blue (RGB) composites of the computed physical values of the picture elements is presented. This work aimed at detection of aerosols above clouds (AAC).