Bursts of polarised single photons from atom-cavity sources

Jan Ole Ernst; Juan Rafael Alvarez; Thomas D. Barrett; Axel Kuhn

doi:10.1088/1361-6455/acf9d2

Bursts of polarised single photons from atom-cavity sources

Jan Ole Ernst
, Juan Rafael Alvarez
, Thomas D. Barrett
, Axel Kuhn

University of Oxford

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

Abstract

Photonic qubits play an instrumental role in the development of advanced quantum technologies, including quantum networking, boson sampling and measurement based quantum computing. A promising framework for the deterministic production of indistinguishable single photons is an atomic emitter coupled to a single mode of a high finesse optical cavity. Polarisation control is an important cornerstone, particularly when the polarisation defines the state of a quantum bit. Here, we propose a scheme for producing bursts of polarised single photons by coupling a generalised atomic emitter to an optical cavity, exploiting a particular choice of quantisation axis. In connection with two re-preparation methods, simulations predict ten-photon bursts coincidence count rates on the order of 1 kHz with single 87 R b atoms trapped in a state of the art optical cavity. This paves the way for novel n-photon experiments with atom-cavity sources.

Original language	English
Article number	205003
Journal	Journal of Physics B: Atomic, Molecular and Optical Physics
Volume	56
Issue number	20
DOIs	https://doi.org/10.1088/1361-6455/acf9d2
Publication status	Published - 28 Oct 2023
Externally published	Yes

Keywords

atomic quantum systems
cavity qed
light-matter interaction
quantum technologies
single photon sources

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10.1088/1361-6455/acf9d2

Cite this

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abstract = "Photonic qubits play an instrumental role in the development of advanced quantum technologies, including quantum networking, boson sampling and measurement based quantum computing. A promising framework for the deterministic production of indistinguishable single photons is an atomic emitter coupled to a single mode of a high finesse optical cavity. Polarisation control is an important cornerstone, particularly when the polarisation defines the state of a quantum bit. Here, we propose a scheme for producing bursts of polarised single photons by coupling a generalised atomic emitter to an optical cavity, exploiting a particular choice of quantisation axis. In connection with two re-preparation methods, simulations predict ten-photon bursts coincidence count rates on the order of 1 kHz with single 87 R b atoms trapped in a state of the art optical cavity. This paves the way for novel n-photon experiments with atom-cavity sources.",

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AU - Ernst, Jan Ole

AU - Alvarez, Juan Rafael

AU - Barrett, Thomas D.

AU - Kuhn, Axel

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Y1 - 2023/10/28

N2 - Photonic qubits play an instrumental role in the development of advanced quantum technologies, including quantum networking, boson sampling and measurement based quantum computing. A promising framework for the deterministic production of indistinguishable single photons is an atomic emitter coupled to a single mode of a high finesse optical cavity. Polarisation control is an important cornerstone, particularly when the polarisation defines the state of a quantum bit. Here, we propose a scheme for producing bursts of polarised single photons by coupling a generalised atomic emitter to an optical cavity, exploiting a particular choice of quantisation axis. In connection with two re-preparation methods, simulations predict ten-photon bursts coincidence count rates on the order of 1 kHz with single 87 R b atoms trapped in a state of the art optical cavity. This paves the way for novel n-photon experiments with atom-cavity sources.

AB - Photonic qubits play an instrumental role in the development of advanced quantum technologies, including quantum networking, boson sampling and measurement based quantum computing. A promising framework for the deterministic production of indistinguishable single photons is an atomic emitter coupled to a single mode of a high finesse optical cavity. Polarisation control is an important cornerstone, particularly when the polarisation defines the state of a quantum bit. Here, we propose a scheme for producing bursts of polarised single photons by coupling a generalised atomic emitter to an optical cavity, exploiting a particular choice of quantisation axis. In connection with two re-preparation methods, simulations predict ten-photon bursts coincidence count rates on the order of 1 kHz with single 87 R b atoms trapped in a state of the art optical cavity. This paves the way for novel n-photon experiments with atom-cavity sources.

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KW - cavity qed

KW - light-matter interaction

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Bursts of polarised single photons from atom-cavity sources

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