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Pulsed quantum continuous-variable optoelectromechanical transducer.

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    This study demonstrates how a noisy mechanical oscillator can mediate entanglement between two non-interacting radiation modes. Optimizing interaction gains is crucial for maximizing this quantum entanglement.

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    Area of Science:

    • Quantum optics
    • Quantum information science
    • Optomechanics

    Background:

    • Direct entanglement of non-interacting radiation modes is challenging.
    • Mechanical oscillators can act as quantum transducers.
    • Noise in mechanical systems can affect quantum states.

    Purpose of the Study:

    • To propose and analyze a setup for entangling two non-interacting radiation modes.
    • To investigate the role of a noisy mechanical oscillator as a mediator.
    • To understand the influence of noise and losses on generated entanglement.

    Main Methods:

    • Utilizing four sequential pulsed quantum resonant interactions.
    • Employing a noisy vibrational mode of a mechanical oscillator as a mediator.
    • Analyzing Gaussian entanglement of the radiation modes.

    Main Results:

    • Confirmed that a noisy mechanical mode can mediate entanglement generation.
    • Demonstrated robustness of the transducer to optical losses.
    • Showed that entanglement is limited without individual optimization of interaction gains.

    Conclusions:

    • The proposed setup successfully mediates entanglement between radiation modes.
    • Individual optimization of interaction gains is necessary for maximal entanglement.
    • The system's performance is influenced by the mechanical bath and optical losses.