Abstract
Abstract. Ice clouds are an important element in the radiative balance of the earth's climate system, but their microphysical and optical properties still are not well constrained, especially ice particle habit and the degree of particle surface roughness. In situ observations have revealed common ice particle habits and evidence for surface roughness, but these observations are limited. An alternative is to infer the ice particle shape and surface roughness from satellite observations of polarized reflectivity since they are sensitive to both particle shape and degree of surface roughness. In this study an adding–doubling radiative transfer code is used to simulate polarized reflectivity for nine different ice habits and one habit mixture, along with 17 distinct levels of the surface roughness. A lookup table (LUT) is constructed from the simulation results and used to infer shape and surface roughness from PARASOL satellite polarized reflectivity data over the ocean. Globally, the retrievals yield a compact aggregate of columns as the most commonly retrieved ice habit. Analysis of PARASOL data from the tropics results in slightly more aggregates than in midlatitude or polar regions. Some level of surface roughness is inferred in nearly 70% of PARASOL data, with mean and median roughness near σ = 0.2 and 0.15, respectively. Tropical region analyses have 20% more pixels retrieved with particle surface roughness than in midlatitude or polar regions. The global asymmetry parameter inferred at a wavelength of 0.865 μm has a mean value of 0.77 and a median value of 0.75.
Highlights
There are still considerable uncertainties in the characterization of the radiation balance of the earth, with the problem of clouds in the earth’s atmosphere near the forefront (Forster et al, 2007)
The ice habit and degree of surface roughness of the ice particles within natural ice clouds can have a large impact on the radiative properties of the clouds and affect estimates of their radiative forcing (Baran, 2009; Wendisch et al, 2005, 2007; Yang et al, 2008a, b; Yi et al, 2013)
To reduce the uncertainties in the characterization of the microphysics of ice clouds, this study uses polarized reflectivity measurements from the PARASOL (Polarization and Anisotropy of Reflectances for Atmospheric Sciences coupled with Observations from a Lidar) platform along with simulations from a full-vector radiative transfer model to infer the habit and degree of surface roughness of particles within the ice clouds
Summary
There are still considerable uncertainties in the characterization of the radiation balance of the earth, with the problem of clouds in the earth’s atmosphere near the forefront (Forster et al, 2007). The ice habit and degree of surface roughness of the ice particles within natural ice clouds can have a large impact on the radiative properties of the clouds and affect estimates of their radiative forcing (Baran, 2009; Wendisch et al, 2005, 2007; Yang et al, 2008a, b; Yi et al, 2013). To reduce the uncertainties in the characterization of the microphysics of ice clouds, this study uses polarized reflectivity measurements from the PARASOL (Polarization and Anisotropy of Reflectances for Atmospheric Sciences coupled with Observations from a Lidar) platform along with simulations from a full-vector radiative transfer model to infer the habit and degree of surface roughness of particles within the ice clouds.
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