Non perturbative approach to Casimir interactions in periodic geometries

TL;DR

This paper develops a non-perturbative method to analyze Casimir forces between periodically deformed metal plates, revealing significant deviations from traditional approximations and highlighting the importance of geometry in quantum interactions.

Contribution

It introduces a detailed non-perturbative path integral approach to compute Casimir forces in complex geometries, including effects of surface edges and non-additivity.

Findings

Identification of two distinct force scaling regimes.

Revealing differences between TE and TM mode behaviors.

Demonstrating strong deviations from proximity force approximation.

Abstract

Due to their collective nature Casimir forces can strongly depend on the geometrical shape of the interacting objects. We study the effect of strong periodic shape deformations of two ideal metal plates on their quantum interaction. A non-perturbative approach which is based on a path integral quantization of the electromagnetic field is presented in detail. Using this approach, we compute the force for the specific case of a flat plate and a plate with a rectangular corrugation. We obtain complementary analytical and numerical results which allow us to identify two different scaling regimes for the force as a function of the mean plate distance, corrugation amplitude and wave length. Qualitative distinctions between transversal electric and magnetic modes are revealed. Our results demonstrate the importance of a careful consideration of the non-additivity of Casimir forces, especially in strongly non-planar geometries. Non-perturbative effects due to surface edges are found. Strong deviations from the commonly used proximity force approximation emerge over a wide range of corrugation wave lengths, even though the surface is composed only of flat segments. We compare our results to that of a perturbative approach and a classical optics approximation.