Design of flexible ultrahigh-Q microcavities in diamond-based photonic crystal slabs

TL;DR

This paper presents a flexible design for ultrahigh-Q diamond-based photonic crystal cavities with small mode volumes, achievable through feasible refractive index modifications, enhancing quantum device applications.

Contribution

The authors introduce a novel, flexible design method for ultrahigh-Q diamond photonic crystal cavities that can be realized with practical index modifications and post-processing techniques.

Findings

Achieved Q factors around 10^7 with index changes of ~0.02

Designed cavities with volumes less than 2 (λ/n)^3

Flexible parameter range for cavity length and index modifications

Abstract

We design extremely flexible ultrahigh-Q diamond-based double-heterostructure photonic crystal slab cavities by modifying the refractive index of the diamond. The refractive index changes needed for ultrahigh-Q cavities with $Q ~ 10^7$, are well within what can be achieved ($\Delta n \sim 0.02$). The cavity modes have relatively small volumes $V<2 (\lambda /n)^3$, making them ideal for cavity quantum electro-dynamic applications. Importantly for realistic fabrication, our design is flexible because the range of parameters, cavity length and the index changes, that enables an ultrahigh-Q is quite broad. Furthermore as the index modification is post-processed, an efficient technique to generate cavities around defect centres is achievable, improving prospects for defect-tolerant quantum architectures.