Overcoming the diffraction limit on the size of dielectric resonators using an amplifying medium

TL;DR

This paper introduces a novel method to surpass the diffraction limit in dielectric resonators by using an active medium to enable subwavelength light localization, leading to potential applications in dielectric lasers and sensors.

Contribution

It demonstrates that an active medium can modify dielectric resonator modes, allowing subwavelength localization and overcoming the diffraction limit without relying on plasmonic structures.

Findings

Active medium induces a gain-assisted mode in dielectric layers.

Phase change on reflection compensates for propagation phase.

Mode exists only at positive gain, enabling subwavelength devices.

Abstract

Existing methods for the localization of light at the nanoscale use either a structure with negative permittivity, by exploiting subwavelength plasmonic resonances, or a dielectric structure with a high refractive index, which reduces the wavelength. In this paper, we provide an alternative to these two methods based on a modification of the modes of dielectric resonators by means of an active medium. We show that an active medium can promote subwavelength light localization in the dielectric structure. We consider a dielectric layer of size substantially smaller than a half-wavelength of light in the dielectric medium, and demonstrate that at a certain value of gain in the active medium, the phase change on reflection at the layer boundaries compensates for the change in phase due to propagation over the layer. At this value of the gain, the gain-assisted mode forms, in which the phase shift during a round trip of the electromagnetic wave is zero. This gain-assisted mode exists only at a positive gain in the dielectric medium, and can be used to create dielectric lasers and sensors of subwavelength size.