Light Scattering from Ultrathin Free Liquid Films: Variation of the Optical Functions with Geometry and Film Thickness*

J. Adin Mann; Karen Caufield; Gerald Gulden

doi:10.1364/JOSA.61.000076

Journal of the Optical Society of America
Vol. 61,
Issue 1,
pp. 76-82
(1971)
•https://doi.org/10.1364/JOSA.61.000076

Light Scattering from Ultrathin Free Liquid Films: Variation of the Optical Functions with Geometry and Film Thickness

J. Adin Mann, Karen Caufield, and Gerald Gulden

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J. Adin Mann, Karen Caufield, and Gerald Gulden, "Light Scattering from Ultrathin Free Liquid Films: Variation of the Optical Functions with Geometry and Film Thickness*," J. Opt. Soc. Am. 61, 76-82 (1971)

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Abstract

Soap-type films can drain to 5 nm when properly stabilized. The light-scattering power of such liquid films was derived by Vrij, in terms of a rippling-slab model. The equations involve five rather complicated functions of the optical parameters: light wavelength, refractive index, angles of incidence and scattering, and the film thickness. The functions oscillate with film thickness. The variations are strictly periodic only in case the angles of incidence and scattering are equal when calculated from the film normal. Calculations are shown in which the film thickness varies from 0 to 50 000 nm. Results of calculations are displayed for the irradiance-modulated pattern. The range of validity of the film light-scattering theory is discussed in view of these results.

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Equations (34)

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θ	G₀G_i	Air–film–air^a		Water–film–water^b

		cycles/17.5 μm	Symmetry	cycles/17.5 μm	Symmetry
60°	G₀G₁	0	⋯	0	⋯
	G₀G₂	0	⋯	0	⋯
	G₀G₃	0	⋯	0	⋯
	G₀G₄		no curve		no curve
65°	G₀G₁	2	unsymmetrical upper and lower curve	$4 \frac{1}{2}$	symmetrical upper and lower curve
	G₀G₂	2	unsymmetrical upper and lower curve	$4 \frac{1}{2}$	symmetrical upper and lower curve
	G₀G₃	1	flat lower curve	$2 \frac{1}{4}$	flat lower curve
	G₀G₄	1	flat lower curve	$2 \frac{1}{4}$	flat lower curve
70°	G₀G₁	4	unsymmetrical upper and lower curve	9	symmetrical upper and lower curve
	G₀G₂	4	unsymmetrical upper and lower curve	9	symmetrical upper and lower curve
	G₀G₃	2	flat lower curve	$4 \frac{1}{2}$	flat lower curve
	G₀G₄	2	flat lower curve	$4 \frac{1}{2}$	flat lower curve
75°	G₀G₁	5	unsymmetrical upper and lower curve	13	symmetrical upper and lower curve
	G₀G₂	5	unsymmetrical upper and lower curve	13	symmetrical upper and lower curve
	G₀G₃	$2 \frac{1}{2}$	flat lower curve	$6 \frac{1}{2}$	flat lower curve
	G₀G₄	$2 \frac{1}{2}$	flat lower curve	$6 \frac{1}{2}$	flat lower curve

θ	G₀G_i	Air–film–air^a		Water–film–water^b

		Cycles/17.5 μm	Symmetry	Cycles/17.5 μm	Symmetry
40°	G₀G₁	2	symmetrical upper and lower curves	4	symmetrical upper and lower curves
	G₀G₂	2	symmetrical upper and lower curves	4	symmetrical upper and lower curves
	G₀G₃	1	flat lower curve	2	flat lower curve
	G₀G₄	1	flat lower curve	2	flat lower curve
35°	G₀G₁	4	symmetrical upper and lower curves	$7 \frac{1}{2}$	symmetrical upper and lower curves
	G₀G₂	4	symmetrical upper and lower curves	$7 \frac{1}{2}$	symmetrical upper and lower curves
	G₀G₃	2	flat lower curve	$3 \frac{3}{4}$	flat lower curve
	G₀G₄	2	flat lower curve	$3 \frac{3}{4}$	flat lower curve
30°	G₀G₁	6	symmetrical upper and lower curves	$10 \frac{1}{2}$	symmetrical upper and lower curves
	G₀G₂	6	symmetrical upper and lower curves	$10 \frac{1}{2}$	symmetrical upper and lower curves
	G₀G₃	3	flat lower curve	$5 \frac{1}{4}$	flat lower curve
	G₀G₂	3	flat lower curve	$5 \frac{1}{4}$	flat lower curve

	Air–film–air		Water–film–water

	Fine period	Beat period	Fine period	Beat period
$\frac{λ = 5460.7 Å}{θ_{0} = 60 °, θ = 65 °}$
G₀G₁, G₀G₂	2800 Å	75 500 Å	3585 Å	331 400 Å
G₀G₃, G₀G₄	2740 Å	152 400 Å	3537 Å	66 750 Å
$\frac{λ = 4358.3 Å}{θ_{0} = 60 °, θ = 65 °}$
G₀G₁, G₀G₂	2235 Å	60 700 Å	2830 Å	26 540 Å
G₀G₃, G₀G₄	2190 Å	121 400 Å	2825 Å	52 950 Å

θ	G₀G_i	Air–film–air^a		Water–film–water^b

		cycles/17.5 μm	Symmetry	cycles/17.5 μm	Symmetry
60°	G₀G₁	0	⋯	0	⋯
	G₀G₂	0	⋯	0	⋯
	G₀G₃	0	⋯	0	⋯
	G₀G₄		no curve		no curve
65°	G₀G₁	2	unsymmetrical upper and lower curve	$4 \frac{1}{2}$	symmetrical upper and lower curve
	G₀G₂	2	unsymmetrical upper and lower curve	$4 \frac{1}{2}$	symmetrical upper and lower curve
	G₀G₃	1	flat lower curve	$2 \frac{1}{4}$	flat lower curve
	G₀G₄	1	flat lower curve	$2 \frac{1}{4}$	flat lower curve
70°	G₀G₁	4	unsymmetrical upper and lower curve	9	symmetrical upper and lower curve
	G₀G₂	4	unsymmetrical upper and lower curve	9	symmetrical upper and lower curve
	G₀G₃	2	flat lower curve	$4 \frac{1}{2}$	flat lower curve
	G₀G₄	2	flat lower curve	$4 \frac{1}{2}$	flat lower curve
75°	G₀G₁	5	unsymmetrical upper and lower curve	13	symmetrical upper and lower curve
	G₀G₂	5	unsymmetrical upper and lower curve	13	symmetrical upper and lower curve
	G₀G₃	$2 \frac{1}{2}$	flat lower curve	$6 \frac{1}{2}$	flat lower curve
	G₀G₄	$2 \frac{1}{2}$	flat lower curve	$6 \frac{1}{2}$	flat lower curve

θ	G₀G_i	Air–film–air^a		Water–film–water^b

		Cycles/17.5 μm	Symmetry	Cycles/17.5 μm	Symmetry
40°	G₀G₁	2	symmetrical upper and lower curves	4	symmetrical upper and lower curves
	G₀G₂	2	symmetrical upper and lower curves	4	symmetrical upper and lower curves
	G₀G₃	1	flat lower curve	2	flat lower curve
	G₀G₄	1	flat lower curve	2	flat lower curve
35°	G₀G₁	4	symmetrical upper and lower curves	$7 \frac{1}{2}$	symmetrical upper and lower curves
	G₀G₂	4	symmetrical upper and lower curves	$7 \frac{1}{2}$	symmetrical upper and lower curves
	G₀G₃	2	flat lower curve	$3 \frac{3}{4}$	flat lower curve
	G₀G₄	2	flat lower curve	$3 \frac{3}{4}$	flat lower curve
30°	G₀G₁	6	symmetrical upper and lower curves	$10 \frac{1}{2}$	symmetrical upper and lower curves
	G₀G₂	6	symmetrical upper and lower curves	$10 \frac{1}{2}$	symmetrical upper and lower curves
	G₀G₃	3	flat lower curve	$5 \frac{1}{4}$	flat lower curve
	G₀G₂	3	flat lower curve	$5 \frac{1}{4}$	flat lower curve

Abstract

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Figures (12)

Tables (3)

Equations (34)

Journal of the Optical Society of America