Quantum error correction beyond qubits

Takao Aoki; Go Takahashi; Tadashi Kajiya; Jun Ichi Yoshikawa; Samuel L. Braunstein; Peter Van Loock; Akira Furusawa

doi:10.1038/nphys1309

Quantum error correction beyond qubits

Takao Aoki^*, Go Takahashi, Tadashi Kajiya, Jun Ichi Yoshikawa, Samuel L. Braunstein, Peter Van Loock, Akira Furusawa

^*この研究の対応する著者

研究成果: Letter › 査読

120 被引用数 (Scopus)

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Quantum computation and communication rely on the ability to manipulate quantum states robustly and with high fidelity. To protect fragile quantum-superposition states from corruption through so-called decoherence noise, some form of error correction is needed. Therefore, the discovery of quantum error correction (QEC) was a key step to turn the field of quantum information from an academic curiosity into a developing technology. Here, we present an experimental implementation of a QEC code for quantum information encoded in continuous variables, based on entanglement among nine optical beams. This nine-wave-packet adaptation of Shors original nine-qubit scheme enables, at least in principle, full quantum error correction against an arbitrary single-beam error.

本文言語	English
ページ（範囲）	541-546
ページ数	6
ジャーナル	Nature Physics
巻	5
号	8
DOI	https://doi.org/10.1038/nphys1309
出版ステータス	Published - 2009 8月
外部発表	はい

ASJC Scopus subject areas

物理学および天文学（全般）

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10.1038/nphys1309

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title = "Quantum error correction beyond qubits",

abstract = "Quantum computation and communication rely on the ability to manipulate quantum states robustly and with high fidelity. To protect fragile quantum-superposition states from corruption through so-called decoherence noise, some form of error correction is needed. Therefore, the discovery of quantum error correction (QEC) was a key step to turn the field of quantum information from an academic curiosity into a developing technology. Here, we present an experimental implementation of a QEC code for quantum information encoded in continuous variables, based on entanglement among nine optical beams. This nine-wave-packet adaptation of Shors original nine-qubit scheme enables, at least in principle, full quantum error correction against an arbitrary single-beam error.",

author = "Takao Aoki and Go Takahashi and Tadashi Kajiya and Yoshikawa, {Jun Ichi} and Braunstein, {Samuel L.} and {Van Loock}, Peter and Akira Furusawa",

note = "Funding Information: This work was partly supported by SCF, GIA, G-COE and PFN commissioned by the MEXT of Japan, and the Research Foundation for Opto-Science and Technology. S.L.B. appreciated discussions with Netta Cohen. P.v.L. acknowledges the DFG for financial support under the Emmy Noether programme. A.F. acknowledges Y. Takeno for preparing the figures. P.v.L. thanks Gerd Leuchs for useful discussions.",

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AU - Kajiya, Tadashi

AU - Yoshikawa, Jun Ichi

AU - Braunstein, Samuel L.

AU - Van Loock, Peter

AU - Furusawa, Akira

N1 - Funding Information: This work was partly supported by SCF, GIA, G-COE and PFN commissioned by the MEXT of Japan, and the Research Foundation for Opto-Science and Technology. S.L.B. appreciated discussions with Netta Cohen. P.v.L. acknowledges the DFG for financial support under the Emmy Noether programme. A.F. acknowledges Y. Takeno for preparing the figures. P.v.L. thanks Gerd Leuchs for useful discussions.

PY - 2009/8

Y1 - 2009/8

N2 - Quantum computation and communication rely on the ability to manipulate quantum states robustly and with high fidelity. To protect fragile quantum-superposition states from corruption through so-called decoherence noise, some form of error correction is needed. Therefore, the discovery of quantum error correction (QEC) was a key step to turn the field of quantum information from an academic curiosity into a developing technology. Here, we present an experimental implementation of a QEC code for quantum information encoded in continuous variables, based on entanglement among nine optical beams. This nine-wave-packet adaptation of Shors original nine-qubit scheme enables, at least in principle, full quantum error correction against an arbitrary single-beam error.

AB - Quantum computation and communication rely on the ability to manipulate quantum states robustly and with high fidelity. To protect fragile quantum-superposition states from corruption through so-called decoherence noise, some form of error correction is needed. Therefore, the discovery of quantum error correction (QEC) was a key step to turn the field of quantum information from an academic curiosity into a developing technology. Here, we present an experimental implementation of a QEC code for quantum information encoded in continuous variables, based on entanglement among nine optical beams. This nine-wave-packet adaptation of Shors original nine-qubit scheme enables, at least in principle, full quantum error correction against an arbitrary single-beam error.

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Quantum error correction beyond qubits

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