A Quantum Repeater Platform based on Single SiV$^-$ Centers in Diamond
with Cavity-Assisted, All-Optical Spin Access and Fast Coherent Driving
- URL: http://arxiv.org/abs/2210.16157v1
- Date: Fri, 28 Oct 2022 14:33:24 GMT
- Title: A Quantum Repeater Platform based on Single SiV$^-$ Centers in Diamond
with Cavity-Assisted, All-Optical Spin Access and Fast Coherent Driving
- Authors: Gregor Bayer, Robert Berghaus, Selene Sachero, Andrea B. Filipovski,
Lukas Antoniuk, Niklas Lettner, Richard Waltrich, Marco Klotz, Patrick Maier,
Viatcheslav Agafonov and Alexander Kubanek
- Abstract summary: Quantum key distribution enables secure communication based on the principles of quantum mechanics.
Quantum repeaters are required to establish large-scale quantum networks.
We present an efficient spin-photon interface for quantum repeaters.
- Score: 45.82374977939355
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Quantum key distribution enables secure communication based on the principles
of quantum mechanics. The distance in fiber-based quantum communication is
limited to about a hundred kilometers due to signal attenuation. Thus, quantum
repeaters are required to establish large-scale quantum networks. Ideal quantum
repeater nodes possess a quantum memory which is efficiently connected to
photons, the carrier of quantum information. Color centers in diamond and, in
particular, the negatively-charged silicon-vacancy centers are promising
candidates to establish such nodes. The major obstacle is an inefficient
connection between the color centers spin to the Gaussian optics of fiber
networks. Here, we present an efficient spin-photon interface. Individual
silicon-vacancy centers coupled to the mode of a hemispherical Fabry-P\'erot
microcavity show Purcell-factors larger than 1 when operated in a bath of
liquid Helium. We demonstrate coherent optical driving with a Rabi frequency of
$290\,\mathrm{MHz}$ and all-optical access to the electron spin in strong
magnetic fields of up to $3.2\,\mathrm{T}$. Spin initialization within
$67\,\mathrm{ns}$ with a fidelity of $80\,\%$ and a lifetime of
$350\,\mathrm{ns}$ are reached inside the cavity. The spin-photon interface is
passively stable, enabled by placing a color center containing nanodiamond in
the hemispherical Fabry-P\'erot mirror structure and by choosing short cavity
lengths. Therefore, our demonstration opens the way to realize quantum repeater
applications.
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