Re-visiting the atmospheric corona

Philip Laven

doi:10.1364/AO.54.000B46

Applied Optics
Vol. 54,
Issue 4,
pp. B46-B53
(2015)
•https://doi.org/10.1364/AO.54.000B46

Re-visiting the atmospheric corona

Philip Laven

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Philip Laven, "Re-visiting the atmospheric corona," Appl. Opt. 54, B46-B53 (2015)

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Abstract

The atmospheric corona is a well-known diffraction phenomenon, typically seen as colored rings surrounding the Sun or Moon. In many respects, Fraunhofer diffraction provides a good explanation of the corona. As the angular sizes of the corona’s rings are inversely proportional to the radius, $r$ , of the spherical particles causing the corona, it should be easy to estimate the particle size from observations and photographs. Noting that some of the techniques commonly used for particle sizing based on diffraction theory can give misleading results for coronas caused by the scattering of sunlight, this paper uses Mie theory simulations to demonstrate that the inner 3 red rings of the corona have angular radii of $θ \approx 16 / r$ , $31 / r$ , and $47 / r$ , when $θ$ is measured in degrees and $r$ is measured in μm.

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	Blue	Green	Red
Maximum	$λ = 0.44 μm$	$λ = 0.51 μm$	$λ = 0.65 μm$
$θ_{1}$	$20.61 / r$	$23.88 / r$	$30.44 / r$
$θ_{2}$	$33.77 / r$	$39.15 / r$	$49.89 / r$
$θ_{3}$	$46.62 / r$	$54.04 / r$	$68.87 / r$
$θ_{4}$	$59.37 / r$	$68.81 / r$	$87.70 / r$
$θ_{5}$	$72.06 / r$	$83.52 / r$	$106.45 / r$
$θ_{6}$	$84.73 / r$	$98.21 / r$	$125.17 / r$

Monochromatic Light	Sunlight
$λ = 0.65 μm$	Diffraction	Mie
—	$16 / r$	$16 / r$
$30.44 / r$	$33 / r$	$31 / r$
$49.89 / r$	$51 / r$	$47 / r$
$68.87 / r$	$71 / r$	—
$87.70 / r$	$91 / r$	—

	Data from Table 1 of [5]		Revised Calculations
$θ$	Designation	Equation	Designation	Equation
3.66°	1st-order red ( $λ = 0.63 μm$ )	$r = 29.51 / θ = 8.07 μm$	First-order red	$r = 16 / θ = 4.37 μm$
5.23°	2nd-order blue ( $λ = 0.49 μm$ )	$r = 37.61 / θ = 7.19 μm$	First-order blue	$r = 20.6 / θ = 3.94 μm$
7.44°	2nd-order red ( $λ = 0.63 μm$ )	$r = 48.35 / θ = 6.5 μm$	Second-order red	$r = 31 / θ = 4.17 μm$

	Diffraction Minima [using Eq. (2)]
Mie	$λ_{0} = 0.486 μm$	$λ_{0} = 0.57 μm$
$16 / r$	$16.98 / r$	$19.91 / r$
$31 / r$	$31.09 / r$	$36.47 / r$
$47 / r$	$45.09 / r$	$52.88 / r$

	Blue	Green	Red
Maximum	$λ = 0.44 μm$	$λ = 0.51 μm$	$λ = 0.65 μm$
$θ_{1}$	$20.61 / r$	$23.88 / r$	$30.44 / r$
$θ_{2}$	$33.77 / r$	$39.15 / r$	$49.89 / r$
$θ_{3}$	$46.62 / r$	$54.04 / r$	$68.87 / r$
$θ_{4}$	$59.37 / r$	$68.81 / r$	$87.70 / r$
$θ_{5}$	$72.06 / r$	$83.52 / r$	$106.45 / r$
$θ_{6}$	$84.73 / r$	$98.21 / r$	$125.17 / r$

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Applied Optics