Electromagnetic forces in photonic crystals

TL;DR

This paper presents a comprehensive numerical method for calculating electromagnetic forces in photonic crystals, revealing how forces depend on energy distribution, wave type, and resonances, with implications for nanostructure manipulation.

Contribution

The authors introduce a versatile real-space Maxwell Stress Tensor-based approach applicable to diverse photonic systems, including complex geometries and frequency-dependent materials.

Findings

Force maxima within photonic band gaps

Sharp attractive and repulsive forces at Mie resonances

Radiation pressure effects can dominate other interactions

Abstract

We develop a general methodology for numerical computations of electromagnetic (EM) fields and forces in matter, based on solving the macroscopic Maxwell's equations in real space and adopting the Maxwell Stress Tensor formalism. Our approach can be applied to both dielectric and metallic systems of frequency-dependent dielectric function; as well as to objects of any size and geometrical properties in principle. We are particularly interested in calculating forces on nanostructures. We find that a body reacts to the EM field by minimising its energy, i.e. it is attracted (repelled) by regions of lower (higher) EM energy. When travelling waves are involved, forces can be additionally understood in terms of momentum exchange between the body and its environment. However when evanescent waves dominate, the forces are complicated, often become attractive and cannot be explained by means of real momentum being exchanged. We study the EM forces induced by a laser beam on a crysta! l of dielectric GaP spheres. We ob serve effects due to the lattice structure, as well as due to single scattering from each sphere. In the former case the two main features are a maximum momentum exchange when the frequency lies within a band gap; and a multitude of force orientations when the Bragg conditions for multiple outgoing waves are met. In the latter case the radiation couples to the EM eigenmodes of isolated spheres (Mie resonances) and very sharp attractive and repulsive forces occur. Depending on the intensity of the incident radiation these forces can overcome all other interactions present (gravitational, thermal and Van der Waals) and may provide the main mechanism for formation of stable structures in colloidal systems.