Arago Optics: Maximal Confinement of Traveling Waves

TL;DR

This paper introduces 'Arago-optics', a novel approach to maximize wave confinement and device efficacy by strategically shaping wave intensity distribution along device perimeters, enhancing focus and resolution.

Contribution

It proposes a new wave engineering concept that optimizes wave confinement by manipulating intensity profiles, integrating geometry and topology for improved optical device performance.

Findings

Maximal wave confinement achieved with perimeter-based intensity distribution.

Enhanced focus and detector resolution through strategic wave profile design.

Applicable to various wave types beyond Gaussian beams.

Abstract

Optics is limited in the 'ray-approximation'-inclusion of wave properties result in additional phenomena and applications; interferometers and diffraction gratings are two manifestations of such non-geometric, physical optics. Incidentally, the most precise measurement ever, at one part per 10^21 in the (2017) Nobel winning discovery of gravitational waves was achieved with an interferometer. Amendments to the properties of the medium promise negative refractive index meta-materials, perfect imaging, light cloaking, and other ultra-natural marvels. Attention to photon phase, correlations, statistics and wavelength independent phase shifts result in singular optics, quantum optics and anholonomy. Here we present another possibility, namely 'Arago-optics' to maximize the efficacy of a device by strategically deploying the key qualities along its perimeter. For instance, in conventional sources, waves are generated with maximum intensity at the core; whereas in an Arago-source, intensity is minimal or zero at the center, but highest on villus stretches at the margins. We reason that for a given size and energy output, this radiation profile, produces the highest concentration of energy at the focus, with the maximal confinement of the wave packet. Likewise, the utmost detector resolution is attained when sensitivity is highest on the perimeter and less at the center. This concept holds beyond ultra-focus and Gaussian beams, but generally applies to beams of 'waves' that show constructive and destructive interference. The idea is particularly well suited for a fresh integration of geometry and topology with electronics and materials into real-time wave engineering.