Coronas are simulated in color by use of the Mie scattering theory of light by small droplets through clouds of finite optical thickness embedded in a Rayleigh scattering atmosphere. The primary factors that affect color, visibility, and number of rings of coronas are droplet size, width of the size distribution, and cloud optical thickness. The color sequence of coronas and iridescence varies when the droplet radius is smaller than ~6-μm. As radius increases to approximately 3.5 μm, new color bands appear at the center of the corona and fade as they move outward. As the radius continues to increase to ~6 μm, successively more inner rings become fixed in the manner described by classical diffraction theory, while outer rings continue their outward migration. Wave clouds or rippled cloud segments produce the brightest and most vivid multiple ringed coronas and iridescence because their integrated drop size distributions along sunbeams are much narrower than in convective or stratiform clouds. The visibility of coronas and the appearance of the background sky vary with cloud optical depth τ. First the corona becomes visible as a white aureole in a blue sky when τ ~ 0.001. Color purity then rapidly increases to an almost flat maximum in the range 0.05 ≤ τ ≤ 0.5 and then decreases, so coronas are almost completely washed out by a bright gray background when τ ≥ 4.
© 2003 Optical Society of America
(010.1290) Atmospheric and oceanic optics : Atmospheric optics
(280.1310) Remote sensing and sensors : Atmospheric scattering
(290.4020) Scattering : Mie theory
(290.4210) Scattering : Multiple scattering
(330.1690) Vision, color, and visual optics : Color
Stanley D. Gedzelman and James A. Lock, "Simulating Coronas in Color," Appl. Opt. 42, 497-504 (2003)