Theory of high-NA imaging in homogeneous thin films

Donis G. Flagello; Tom Milster; Alan E. Rosenbluth

doi:10.1364/JOSAA.13.000053

Journal of the Optical Society of America A
Vol. 13,
Issue 1,
pp. 53-64
(1996)
•https://doi.org/10.1364/JOSAA.13.000053

Theory of high-NA imaging in homogeneous thin films

Donis G. Flagello, Tom Milster, and Alan E. Rosenbluth

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Donis G. Flagello, Tom Milster, and Alan E. Rosenbluth, "Theory of high-NA imaging in homogeneous thin films," J. Opt. Soc. Am. A 13, 53-64 (1996)

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Abstract

A description is given of a modeling technique that is used to explore three-dimensional image distributions formed by high numerical aperture (NA > 0.6) lenses in homogeneous, isotropic, linear, and source-free thin films. The approach is based on a plane-wave decomposition in the exit pupil. Factors that are due to polarization, aberration, object transmittance, propagation, and phase terms are associated with each plane-wave component. These are combined with a modified thin-film matrix technique in a derivation of the total field amplitude at each point in the film by a coherent vector sum over all plane waves. One then calculates the image distribution by squaring the electric-field amplitude. The model is used to show how asymmetries present in the polarized image change with the influence of a thin film. Extensions of the model to magneto-optic thin films are discussed.

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Component	Full Assembly	Subassembly
Transverse reflection	$r = \frac{A_{r I}}{A_{i I}}$	$r_{II} = \frac{A_{r II}}{A_{i II}}$
Transverse transmission	$τ = \frac{A_{t m}}{A_{i I}}$	$τ_{II} = \frac{A_{t m}}{A_{i II}}$
Axial reflection	$r_{z} = \frac{A_{r Iz}}{A_{i Iz}}$	$r_{II z} = \frac{A_{r II z}}{A_{i II z}}$
Axial transmission	$τ_{z} = \frac{A_{t m z}}{A_{i Iz}}$	$τ_{II z} = \frac{A_{t m z}}{{A_{i}}_{II z}}$

Film Assembly	Optics
N′ = 1	NA′ = 0.95, λ = 0.442 μm
N₁ = 1.656 − i0.004, d₁ = 1 μm	NA ≫ 1
	x-polarized
N_m = 1.656 − i0.004	O(x, y) = δ(x, y) W = 0, z₀ = 0

Film Assembly	Optics
N′ = 1	NA′ = 0.95, λ = 0.442 μm
N₁ = 1.656 − i0.004, d₁ = 1 μm	NA = 0.048
	O(x, y) = tribar, 3 bars of unit amplitude on an opaque field
N_m = 1.656 − i0.004	W = 0, z₀ = 0, m = 0.05

Component	Full Assembly	Subassembly
Transverse reflection	$r = \frac{A_{r I}}{A_{i I}}$	$r_{II} = \frac{A_{r II}}{A_{i II}}$
Transverse transmission	$τ = \frac{A_{t m}}{A_{i I}}$	$τ_{II} = \frac{A_{t m}}{A_{i II}}$
Axial reflection	$r_{z} = \frac{A_{r Iz}}{A_{i Iz}}$	$r_{II z} = \frac{A_{r II z}}{A_{i II z}}$
Axial transmission	$τ_{z} = \frac{A_{t m z}}{A_{i Iz}}$	$τ_{II z} = \frac{A_{t m z}}{{A_{i}}_{II z}}$

Film Assembly	Optics
N′ = 1	NA′ = 0.95, λ = 0.442 μm
N₁ = 1.656 − i0.004, d₁ = 1 μm	NA ≫ 1
	x-polarized
N_m = 1.656 − i0.004	O(x, y) = δ(x, y) W = 0, z₀ = 0

Abstract

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Equations (59)

Journal of the Optical Society of America A