The Spectral Domain Snell Law in Diffusion-Wave Fields

TL;DR

This paper reveals a spectral form of Snell law in diffusion-wave fields, showing hidden refraction behavior governed by media properties, despite the absence of traditional geometric refraction in diffusive processes.

Contribution

It introduces a spectral Snell law for diffusion waves, linking refraction ratios to media constitutive relations and uncovering a new paradigm in diffusion dynamics.

Findings

Spectral eigenmodes obey Snell-type refraction relations.

Inverse Fourier-Laplace transform suppresses real-space refraction angles.

Diffusion media properties govern spectral refraction ratios.

Abstract

Snell law is traditionally regarded as a hallmark of phase-propagating phenomena such as optical, acoustic, elastic, electromagnetic, and quantum waves. In contrast, purely diffusive processes, such as Fourier heat conduction and chemical diffusion, are generally considered incapable of exhibiting refractive/reflective behavior. In this letter, we demonstrate that although diffusion waves including thermal diffusion, mass diffusion, Lindblad quantum diffusion, and electromagnetic diffusion do not follow Snell law in either time or frequency-domain, nevertheless they obey a spectral form of Snell law which reveals a hidden analog of wave refraction/reflection within the mathematical structure of diffusion dynamics. Remarkably, the spectral refraction ratio is governed not by the diffusion coefficient itself but by the constitutive relations of the media across the interface, establishing a new physical paradigm for diffusion-wave fields. Importantly, while each spectral eigenmode satisfies a rigorous Snell-type refraction relation, the inverse Fourier-Laplace transformation mixes these modes and suppresses any persistent real-space refraction angle, thereby reconciling the modal-level directionality with the long-standing absence of geometric refraction in diffusive systems.