A Diamond Nanowire Single Photon Antenna

TL;DR

This paper presents a novel diamond nanowire device with an NV center that efficiently emits single photons at room temperature, advancing quantum communication and sensing technologies.

Contribution

It introduces a diamond nanowire design that significantly enhances single photon collection efficiency and reduces power requirements for NV center-based sources.

Findings

Increased photon collection by an order of magnitude.

Operates effectively at room temperature.

Reduces power consumption by an order of magnitude.

Abstract

The development of a robust light source that emits one photon at a time is an outstanding challenge in quantum science and technology. Here, at the transition from many to single photon optical communication systems, fully quantum mechanical effects may be utilized to achieve new capabilities, most notably perfectly secure communication via quantum cryptography. Practical implementations place stringent requirements on the device properties, including stable photon generation, room temperature operation, and efficient extraction of many photons. Single photon light emitting devices based on fluorescent dye molecules, quantum dots, and carbon nanotube material systems have all been explored, but none have simultaneously demonstrated all criteria. Here, we describe the design, fabrication, and characterization of a bright source of single photons consisting of an individual Nitrogen-vacancy color center (NV center) in a diamond nanowire operating in ambient conditions. The nanowire plays a positive role in increasing the number of single photons collected from the NV center by an order of magnitude over devices based on bulk diamond crystals, and allows operation at an order of magnitude lower power levels. This result enables a new class of nanostructured diamond devices for room temperature photonic and quantum information processing applications, and will also impact fields as diverse as biological and chemical sensing, opto-mechanics, and scanning-probe microscopy.