Reversal of photon-scattering errors in atomic qubits

Nitzan Akerman; Shlomi Kotler; Yinnon Glickman; Roee Ozeri

doi:https://doi.org/10.1103/PhysRevLett.109.103601

Reversal of photon-scattering errors in atomic qubits

Nitzan Akerman, Shlomi Kotler, Yinnon Glickman, Roee Ozeri

Weizmann Institute of Science

Research output: Contribution to journal › Article › peer-review

Abstract

Spontaneous photon scattering by an atomic qubit is a notable example of environment-induced error and is a fundamental limit to the fidelity of quantum operations. In the scattering process, the qubit loses its distinctive and coherent character owing to its entanglement with the photon. Using a single trapped ion, we show that by utilizing the information carried by the photon, we are able to coherently reverse this process and correct for the scattering error. We further used quantum process tomography to characterize the photon-scattering error and its correction scheme and demonstrate a correction fidelity greater than 85% whenever a photon was measured.

Original language	English
Article number	103601
Journal	Physical review letters
Volume	109
Issue number	10
DOIs	https://doi.org/10.1103/PhysRevLett.109.103601
State	Published - 4 Sep 2012

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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https://doi.org/10.1103/PhysRevLett.109.103601

http://arxiv.org/abs/1111.1622License: Other

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title = "Reversal of photon-scattering errors in atomic qubits",

abstract = "Spontaneous photon scattering by an atomic qubit is a notable example of environment-induced error and is a fundamental limit to the fidelity of quantum operations. In the scattering process, the qubit loses its distinctive and coherent character owing to its entanglement with the photon. Using a single trapped ion, we show that by utilizing the information carried by the photon, we are able to coherently reverse this process and correct for the scattering error. We further used quantum process tomography to characterize the photon-scattering error and its correction scheme and demonstrate a correction fidelity greater than 85% whenever a photon was measured.",

author = "Nitzan Akerman and Shlomi Kotler and Yinnon Glickman and Roee Ozeri",

note = "Israeli Science Foundation; Minerva Foundation; German-Israeli Foundation for Scientific Research; Crown Photonics Center; Wolfson Family Charitable Trust; Yeda-Sela Center for Basic Research; David Dickstein of FranceThis research was supported by the Israeli Science Foundation, the Minerva Foundation, the German-Israeli Foundation for Scientific Research, the Crown Photonics Center, the Wolfson Family Charitable Trust, Yeda-Sela Center for Basic Research, and David Dickstein of France.",

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AU - Akerman, Nitzan

AU - Kotler, Shlomi

AU - Glickman, Yinnon

AU - Ozeri, Roee

N1 - Israeli Science Foundation; Minerva Foundation; German-Israeli Foundation for Scientific Research; Crown Photonics Center; Wolfson Family Charitable Trust; Yeda-Sela Center for Basic Research; David Dickstein of FranceThis research was supported by the Israeli Science Foundation, the Minerva Foundation, the German-Israeli Foundation for Scientific Research, the Crown Photonics Center, the Wolfson Family Charitable Trust, Yeda-Sela Center for Basic Research, and David Dickstein of France.

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N2 - Spontaneous photon scattering by an atomic qubit is a notable example of environment-induced error and is a fundamental limit to the fidelity of quantum operations. In the scattering process, the qubit loses its distinctive and coherent character owing to its entanglement with the photon. Using a single trapped ion, we show that by utilizing the information carried by the photon, we are able to coherently reverse this process and correct for the scattering error. We further used quantum process tomography to characterize the photon-scattering error and its correction scheme and demonstrate a correction fidelity greater than 85% whenever a photon was measured.

AB - Spontaneous photon scattering by an atomic qubit is a notable example of environment-induced error and is a fundamental limit to the fidelity of quantum operations. In the scattering process, the qubit loses its distinctive and coherent character owing to its entanglement with the photon. Using a single trapped ion, we show that by utilizing the information carried by the photon, we are able to coherently reverse this process and correct for the scattering error. We further used quantum process tomography to characterize the photon-scattering error and its correction scheme and demonstrate a correction fidelity greater than 85% whenever a photon was measured.

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M3 - مقالة

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Reversal of photon-scattering errors in atomic qubits

Abstract

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