Rainbow-enhanced forward and backward glory scattering

Dean S. Langley; Michael J. Morrell

doi:10.1364/AO.30.003459

Applied Optics
Vol. 30,
Issue 24,
pp. 3459-3467
(1991)
•https://doi.org/10.1364/AO.30.003459

Rainbow-enhanced forward and backward glory scattering

Dean S. Langley and Michael J. Morrell

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Dean S. Langley and Michael J. Morrell, "Rainbow-enhanced forward and backward glory scattering," Appl. Opt. 30, 3459-3467 (1991)

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Abstract

When the refractive index m of a sphere is such that rainbows occur in the forward or backward direction, the glory scattering becomes exceptionally strong. A number of these refractive-index values have been determined from the geometry of ray paths. A physical-optics model of the scattering leads to an a²x^4/3 dependence in the scattered irradiance, where a is the radius of the sphere, and x = ka is the size parameter. Normal glory scattering gives an irradiance proportional to x. Mie theory computations illustrate the presence of rainbow glories at predicted m values and the x^4/3 irradiance factor. As in normal glory scattering, the rainbow-enhanced glory light contains a strong cross-polarized component. Experiments using single glass spheres immersed in liquids show the predicted cross-polarized scattering with a sensitive dependence on m.

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Equations (29)

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(P, L)	m_P_,_L*	tan ρ	ρ (deg)	θ (deg)
(3,1)	$\sqrt{6 \sqrt{3}} - p \approx 1.17996$	${(\sqrt{12} / 3 + 1)}^{1 / 2}$	55.735	77.206
(4,1)	$\frac{4}{9} \sqrt{6} \approx 1.08866$	$\sqrt{5}$	65.905	83.621
(4,2)	$4 {(\frac{10 \sqrt{10} - 28)}{27})}^{1 / 2} \approx 1.46521$	${(2 \sqrt{10} / 15 + 1 / 3)}^{1 / 2}$	40.987	73.948
(5,2)	$\frac{5}{4} = 1.25$	$\sqrt{5 / 3}$	52.239	81.194
(6,1)	$\frac{4}{125} (9 \sqrt{7} - 8 \sqrt{3}) \sqrt{6 + \sqrt{21}} \approx 1.03634$	${(7 + 4 \sqrt{21} / 3)}^{1 / 2}$	74.561	87.364
(6,3)	$\frac{4}{125} (9 \sqrt{7} + 8 \sqrt{3}) \sqrt{6 - \sqrt{21}} \approx 1.43507$	${(7 - 4 \sqrt{21} / 3)}^{1 / 2}$	43.330	79.981
(7,2)	$\frac{7}{27} (2 \sqrt{7} - 1) \approx 1.11261$	${(7 / 3 + 2 \sqrt{7} / 3)}^{1 / 2}$	63.709	85.963
(7,4)	$\frac{7}{27} (2 \sqrt{7} + 1) \approx 1.63113$	${(7 / 3 - 2 \sqrt{7} / 3)}^{1 / 2}$	37.040	79.281

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