Universal Routing of Light via Optical Thermodynamics

TL;DR

This paper introduces a universal optical routing mechanism based on thermodynamic principles, enabling light to reliably localize in a ground state within nonlinear multimode systems, regardless of initial conditions.

Contribution

It demonstrates a novel optical thermodynamic process that causes light to condense into a localized ground state, a phenomenon not achievable in linear systems, with experimental validation.

Findings

Light universally condenses into a ground state in nonlinear arrays

Optical temperature approaches near zero during the process

Potential applications in beam steering and nonlinear beam shaping

Abstract

Understanding and exploiting the dynamics of complex nonlinear systems is nowadays at the core of a broad range of scientific and technological endeavors. Within the optical domain, light evolution in a nonlinear multimode environment presents a formidable problem, as its chaotic evolution often hinders predictive insights. Recently, an optical thermodynamic framework has been put forward that, in a systematic manner, can not only predict but also harness the intricate behavior of these systems. In this work, by deploying entropic principles, we demonstrate a counterintuitive optical process in which light, launched into any input port of a judiciously designed nonlinear array, universally channels into a tightly localized ground state, a response that is completely unattainable in linear conservative arrangements. This phenomenon arises from the interplay between lattice structure and the way the kinetic and nonlinear Hamiltonian components unfold, leading to two optical thermal processes: a Joule-Thomson-like expansion followed by mode thermalization. Experimentally, this effect is demonstrated in properly configured nonlinear time-synthetic mesh lattices, where the optical temperature approaches near zero, causing light to condense at a single spot, regardless of the initial excitation position. The effect demonstrated here opens new avenues for applying the principles of optical thermodynamics in realizing novel optical functionalities, such as all-optical beam steering, multiplexing, and nonlinear beam shaping in high-power regimes, while also offering a greater understanding of the remarkable physics of light-matter interactions in multimode nonlinear systems.