Differential Refractive index sensor based on Photonic molecules and defect cavities

TL;DR

This paper introduces a novel microwave refractive index sensor using photonic molecules and defect cavities, demonstrating high sensitivity and linear response, with potential extension to optical sensing.

Contribution

The work presents a new sensor design based on photonic molecules and defect cavities, validated through experiments and simulations, with potential for optical applications.

Findings

Sensor exhibits a wide photonic stop band with localized states.

Defect mode is highly sensitive to dielectric permittivity changes.

Sensor response is linear across the tested range.

Abstract

We present a novel differential refractive index sensor based on arrays of photonic molecules (PM) of dielectric cylinders and two structural defect cavities. The transmission spectrum of the photonic proposed structure as sensor shows a wide photonic stop band with two localized states. One of them, the reference state, is bound to a decagonal ring of cylinders and the other, the sensing state, to the defect cavities of the lattice. It is shown that defect mode is very sensitive to the presence of materials with dielectric permittivity different from that of the surrounding cylinders while the state in the PM is not affected by their presence. This behavior allows to design a device for sensing applications. A prototype of the sensor, in the microwave region, was built using a matrix of 3x2 PM arrays made of soda-lime glass cylinders (dielectric permittivity of 4.5). The transmission spectra was measured in the microwave range (8-12 GHz) with samples of different refractive index inserted in the defect cavities. Simulations with Finite Integration time-domain Method are in good agreement with experiments. We find that the response of the sensor is linear. Device measurement range is determined by the dielectric constant of the cylinders that make up the device. The results here presented in the microwave region can be extrapolated to the visible range due to scale invariance of Maxwell equations. This make our prototype a promising structure as sensor also in the optical range.