# Isolated spin qubits in SiC with a high-fidelity infrared spin-to-photon   interface

**Authors:** David J. Christle, Paul V. Klimov, Charles F. de las Casas,, Kriszti\'an Sz\'asz, Viktor Iv\'ady, Valdas Jokubavicius, Jawad ul Hassan,, Mikael Syv\"aj\"arvi, William F. Koehl, Takeshi Ohshima, Nguyen T. Son, Erik, Janz\'en, \'Ad\'am Gali, and David D. Awschalom

arXiv: 1702.07330 · 2017-06-28

## TL;DR

This paper demonstrates a high-fidelity spin-to-photon interface using divacancies in SiC, highlighting their potential for quantum communication due to long coherence times and optical addressability.

## Contribution

It presents the first demonstration of high-fidelity spin-to-photon conversion in isolated divacancies in epitaxial SiC films, with insights into their optical and spin coherence properties.

## Key findings

- Divacancies in 4H-SiC exhibit minimal spin-mixing.
- Optical linewidths are comparable to those in recent entanglement experiments.
- 3C-SiC divacancies have millisecond Hahn-echo coherence times.

## Abstract

The divacancies in SiC are a family of paramagnetic defects that show promise for quantum communication technologies due to their long-lived electron spin coherence and their optical addressability at near-telecom wavelengths. Nonetheless, a mechanism for high-fidelity spin-to-photon conversion, which is a crucial prerequisite for such technologies, has not yet been demonstrated. Here we demonstrate a high-fidelity spin-to-photon interface in isolated divacancies in epitaxial films of 3C-SiC and 4H-SiC. Our data show that divacancies in 4H-SiC have minimal undesirable spin-mixing, and that the optical linewidths in our current sample are already similar to those of recent remote entanglement demonstrations in other systems. Moreover, we find that 3C-SiC divacancies have millisecond Hahn-echo spin coherence time, which is among the longest measured in a naturally isotopic solid. The presence of defects with these properties in a commercial semiconductor that can be heteroepitaxially grown as a thin film on shows promise for future quantum networks based on SiC defects.

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Source: https://tomesphere.com/paper/1702.07330