Inverse design of focused vector beams for mode excitation in optical nanoantennas

TL;DR

This paper introduces an inverse design method for creating focused vector beams to selectively excite specific eigenmodes in optical nanoantennas, improving precision over traditional forward beam-shaping techniques.

Contribution

The work presents a novel inverse design approach for mode-specific excitation in nanoantennas using backward propagation of vector beams, enhancing accuracy in mode matching.

Findings

Successfully designed focused vector beams for silicon nanostructures.

Achieved more precise mode-matching compared to forward beam-shaping.

Demonstrated applicability to various nanostructure configurations.

Abstract

We propose a free-space, inverse design of nanostructure's effective mode-matching fields via a backward propagation of tightly focused vector beams to the pupil plane of an aplanatic system of high numerical aperture. First, we study the nanostructure's eigenmodes without considering any excitation fields and then extract the modal near fields in the focal plane. Each modal field is then taken as the desired focal field, the band-limited waves of which are backward propagated to the pupil plane via a reversal of the Richards--Wolf vector diffraction formula. The pupil fields can be designed to be genuinely paraxial by associating the longitudinal electric/magnetic field component with the radial one on the reference sphere. The inversely designed pupil field in turn is propagated forwardly into the focal region to generate the designed focal field, whose distribution over the nanostructure's surface is used to evaluate the overlap between the designed focal field and the modal fields, i.e., the modal expansion coefficients. Studies for a silicon nanodisk monomer, dimer, and tetramer demonstrate the ability of our inverse approach to design the necessary tightly focused vector field that can effectively and exclusively match a certain eigenmode of interest. Compared with the forward beam-shaping method, the inverse design approach tends to yield quantitatively more precise mode-matching field profiles. This work can have a significant impact on optical applications that rely on controllable and tunable mode excitation and light scattering.