Photonic Architecture for Scalable Quantum Information Processing in Diamond

Photonic Architecture for Scalable Quantum Information Processing in Diamond

Physics and information are intimately connected, and the ultimate information processing devices will be those that harness the principles of quantum mechanics. Many physical systems have been identified as candidates for quantum information processing, but none of them are immune from errors. The...

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Main Authors: Kae Nemoto, Michael Trupke, Simon J. Devitt, Ashley M. Stephens, Burkhard Scharfenberger, Kathrin Buczak, Tobias Nöbauer, Mark S. Everitt, Jörg Schmiedmayer, William J. Munro
Format: Article
Language:English
Published: American Physical Society 2014-08-01
Series:Physical Review X
Online Access:http://doi.org/10.1103/PhysRevX.4.031022
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spelling doaj-08e322532dfb4ef7bc88a2752a56265a2020-11-24T23:32:53ZengAmerican Physical SocietyPhysical Review X2160-33082014-08-014303102210.1103/PhysRevX.4.031022Photonic Architecture for Scalable Quantum Information Processing in DiamondKae NemotoMichael TrupkeSimon J. DevittAshley M. StephensBurkhard ScharfenbergerKathrin BuczakTobias NöbauerMark S. EverittJörg SchmiedmayerWilliam J. MunroPhysics and information are intimately connected, and the ultimate information processing devices will be those that harness the principles of quantum mechanics. Many physical systems have been identified as candidates for quantum information processing, but none of them are immune from errors. The challenge remains to find a path from the experiments of today to a reliable and scalable quantum computer. Here, we develop an architecture based on a simple module comprising an optical cavity containing a single negatively charged nitrogen vacancy center in diamond. Modules are connected by photons propagating in a fiber-optical network and collectively used to generate a topological cluster state, a robust substrate for quantum information processing. In principle, all processes in the architecture can be deterministic, but current limitations lead to processes that are probabilistic but heralded. We find that the architecture enables large-scale quantum information processing with existing technology.http://doi.org/10.1103/PhysRevX.4.031022
collection DOAJ
language English
format Article
sources DOAJ
author Kae Nemoto
Michael Trupke
Simon J. Devitt
Ashley M. Stephens
Burkhard Scharfenberger
Kathrin Buczak
Tobias Nöbauer
Mark S. Everitt
Jörg Schmiedmayer
William J. Munro
spellingShingle Kae Nemoto
Michael Trupke
Simon J. Devitt
Ashley M. Stephens
Burkhard Scharfenberger
Kathrin Buczak
Tobias Nöbauer
Mark S. Everitt
Jörg Schmiedmayer
William J. Munro
Photonic Architecture for Scalable Quantum Information Processing in Diamond
Physical Review X
author_facet Kae Nemoto
Michael Trupke
Simon J. Devitt
Ashley M. Stephens
Burkhard Scharfenberger
Kathrin Buczak
Tobias Nöbauer
Mark S. Everitt
Jörg Schmiedmayer
William J. Munro
author_sort Kae Nemoto
title Photonic Architecture for Scalable Quantum Information Processing in Diamond
title_short Photonic Architecture for Scalable Quantum Information Processing in Diamond
title_full Photonic Architecture for Scalable Quantum Information Processing in Diamond
title_fullStr Photonic Architecture for Scalable Quantum Information Processing in Diamond
title_full_unstemmed Photonic Architecture for Scalable Quantum Information Processing in Diamond
title_sort photonic architecture for scalable quantum information processing in diamond
publisher American Physical Society
series Physical Review X
issn 2160-3308
publishDate 2014-08-01
description Physics and information are intimately connected, and the ultimate information processing devices will be those that harness the principles of quantum mechanics. Many physical systems have been identified as candidates for quantum information processing, but none of them are immune from errors. The challenge remains to find a path from the experiments of today to a reliable and scalable quantum computer. Here, we develop an architecture based on a simple module comprising an optical cavity containing a single negatively charged nitrogen vacancy center in diamond. Modules are connected by photons propagating in a fiber-optical network and collectively used to generate a topological cluster state, a robust substrate for quantum information processing. In principle, all processes in the architecture can be deterministic, but current limitations lead to processes that are probabilistic but heralded. We find that the architecture enables large-scale quantum information processing with existing technology.
url http://doi.org/10.1103/PhysRevX.4.031022
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