Simultaneous high Q/V-ratio and optimized far-field emission pattern in diamond slot-bridge nanobeam cavity

At a Glance

Metadata	Details
Publication Date	2021-05-18
Journal	Results in Physics
Authors	Mohannad Al‐Hmoud, Smail Bougouffa
Institutions	Imam Mohammad ibn Saud Islamic University
Citations	4

Abstract

We present a design for a slot-bridge nanobeam cavity that supports ultrahigh Q/V and optimized far-field emission pattern, and operates at the zero-phonon transition (637nm) of the nitrogen-vacancy color centers in diamond. The slot-bridge cavity is formed by introducing a diamond bridge at the center of the air region of a slotted cavity. As a result of the boundary condition on the parallel component of the electric field, the electric field in the bridge region is the same as that in the slot. This results in a further reduction of the mode volume. Optimized slot-bridge cavities with a calculated Q factor of 6×106 and mode volume of Veff=0.28(λ/n)3have been realized. In comparison to nanobeam cavities, the mode volume is reduced by a factor of 139. The far-field pattern of a slot-bridge cavity is optimized by using the band folding method and by adding small air-slot extensions to the two closest air-holes surrounding the cavity. A high Q of 9.8×105 and a small mode volume of Veff=0.011(λ/n)3 is realized for this design. Therefore, this type of cavities would allow for the realization of efficient single-photon sources. Our results are important for fundamental studies, like cavity quantum electrodynamics, as well as applications in quantum information processing based on diamond where high quality-factor and ultrasmall mode volume are required.

Tech Support

Related Applications

Our scientists have selected these diamond solutions based on the research abstract.

Recommended

High Concentration Quantum Grade Single Crystal Diamond

View Specs →

Recommended

Boron Doped Single Crystal Diamond Plate

View Specs →

Recommended

Single Crystal Cvd Diamond Plate

View Specs →

Can’t find what you need? Explore our full catalog of Diamond Materials

Original Source

• DOI: https://doi.org/10.1016/j.rinp.2021.104314

References

1. 2010 - Quantum computers [Crossref]
2. 2006 - Single defect centres in diamond: A review [Crossref]
3. 2000 - Stable Solid-State Source of Single Photons [Crossref]
4. 2002 - Single Photon Quantum Cryptography [Crossref]
5. 2011 - Diamond-based single-photon emitters [Crossref]
6. 2018 - Two-dimensional photonic crystal slab nanocavities on bulk single-crystal diamond [Crossref]
7. 2011 - One- and two-dimensional photonic crystal microcavities in single crystal diamond [Crossref]
8. 2017 - Nanodiamonds with photostable, sub-gigahertz linewidth quantum emitters [Crossref]
9. 2010 - A diamond nanowire single-photon source [Crossref]

---

Reads Similar to This

An integrated and scalable experimental system for nitrogen-vacancy ensemble magnetometry One-Way Quantum Repeater Based on Near-Deterministic Photon-Emitter Interfaces Suppressing Spectral Diffusion of Emitted Photons with Optical Pulses

← Older Paper Quantum embedding methods for correlated excited states of point defects - Case studies and challenges Newer Paper → Deterministic preparation of W states via spin-photon interactions