Large field enhancement obtained by combining Fabry-Perot resonance and Rayleigh anomaly in photonic crystal slabs

TL;DR

This paper demonstrates that combining Fabry-Perot resonance with Rayleigh anomaly in photonic crystal slabs can significantly enhance light scattering, leading to large reflection or transmission coefficients useful for various optical applications.

Contribution

The study introduces an effective medium design method for resonant photonic crystal slabs that achieve large field enhancements through combined resonances.

Findings

Enhanced light scattering with large reflection/transmission coefficients

Four orders of magnitude increase in light intensity in low index contrast slabs

Potential applications in fields requiring strong propagating fields

Abstract

By applying the properties of Fabry-Perot resonance and Rayleigh anomaly, we have shown that a photonic crystal slab can scatter the light from an incident plane wave into a diffracted light with a very large reflection or transmission coefficient. The enhanced field is either a propagating diffraction order (with a grazing angle of diffraction) or a weakly evanescent order, so it can be particularly useful for applications requiring an enhanced propagating field (or an enhanced field with a low attenuation). An efficient effective medium technique is developed for the design of the resonant photonic crystal slabs. Numerical simulations have shown that photonic crystal slabs with low index contrast, such as the ones found in the cell wall of diatoms, can enhance the intensity of the incident light by four orders of magnitude.