Analytic approach for calculating transmitted electromagnetic fields through a slot array in deep sub-wavelength regime

TL;DR

This paper introduces a generalized analytical model for calculating electromagnetic fields transmitted through arbitrary slot arrays in deep sub-wavelength regimes, offering faster computation and applicability to complex composite surfaces.

Contribution

The paper extends previous single-slot analysis to arbitrary slot arrays with variable parameters, enabling efficient calculation of electromagnetic fields without large matrix inversions.

Findings

Model accurately predicts transmitted fields in complex slot arrays.

Significantly reduces computational time compared to FDTD and wave number methods.

Applicable to composite surfaces with different dielectric materials.

Abstract

For the diffraction of an incident plane electromagnetic wave by a slotted metallic film, the previous analytical calculation for a single slot [Technical Phys. 50, 1076 (2005)] is generalized into a model for an arbitrary linear array of slots with variable slot width, slot separation and slot dielectric material. The advantage as well as the effectiveness of the generalized model presented in this paper are best described by enabling calculation of a continuous spatial distribution of an electromagnetic field by inverting a small discrete coefficient matrix spanned by both the slot index and the slot-eigenmode index for a set of linear equations. In comparisons with well-known plane-wave and finite-difference time-domain methods, inverting a large matrix, in wave number space for the former case and in real space at each time step for the latter case, can be avoided to greatly speed up numerical calculations. In addition, based on a partial-domain method, the formalism presented here can be employed to treat a composite surface (e.g., a slotted metal film with different dielectric materials in the slots), while the analytical Green's function approach [J. Opt. A: Pure Appl. Opt. 8, S191 (2006)] becomes intractable in this case. Some numerical results are presented as a demonstration of this new analytical model.