Towards optical sensing with hyperbolic metamaterials

TL;DR

This paper explores a theoretical optical sensing method using porous hyperbolic metamaterials infiltrated with fluids, demonstrating high sensitivity of the cone angle to refractive index changes, which could enhance sensing capabilities.

Contribution

It introduces a novel sensing mechanism based on cone angle sensitivity in infiltrated hyperbolic metamaterials, with detailed parametric analysis showing potential for high sensitivity.

Findings

Sensitivity $d \theta_c / d n_b$ can exceed 500 degrees per refractive index unit.

High sensitivity is achieved when the hyperbolic material's eigenvalue approaches zero.

Porosity and material parameters significantly influence sensing sensitivity.

Abstract

A possible means of optical sensing, based on a porous hyperbolic material which is infiltrated by a fluid containing an analyte to be sensed, was investigated theoretically. The sensing mechanism relies on the observation that extraordinary plane waves propagate in the infiltrated hyperbolic material only in directions enclosed by a cone aligned with the optic axis of the infiltrated hyperbolic material. The angle this cone subtends to the plane perpendicular to the optic axis is $\theta_c$. The sensitivity of $\theta_c$ to changes in refractive index of the infiltrating fluid, namely $n_b$, was explored; also considered were the permittivity parameters and porosity of the hyperbolic material, as well as the shape and size of its pores. Sensitivity was gauged by the derivative $d \theta_c / d n_b$. In parametric numerical studies, values of $d \theta_c / d n_b$ in excess of 500 degrees per refractive index unit were computed, depending upon the constitutive parameters of the porous hyperbolic material and infiltrating fluid, and the nature of the porosity. In particular, it was observed that exceeding large values of $d \theta_c / d n_b$ could be attained as the negative--valued eigenvalue of the infiltrated hyperbolic material approached zero.