Heralded Scheme for Entangling Microwave-optical Modes in Cavity Piezo-optomechanics

ORAL

Abstract

Quantum state transfer between microwave and optical frequencies is important in the development of modular quantum computation. Most schemes to realize such a hybrid interface are based on direct quantum transduction, which, nevertheless, has to full stringent requirements such as high conversion efficiency and low added noise. Despite all the recent remarkable efforts, in practice, building a direct microwave-optical quantum transducer still remains a challenge. A possible way out is to generate entanglement between the two modes and use it as a resource for microwave-optical modes transfer through teleportation. In this work, we propose a heralded scheme to entangle microwave and optical modes via parametric down conversion in a generic cavity piezo-optomechanical system. By post-selecting a two-mode squeezed vacuum state, entangled microwave-optical photon pairs can be generated. The entanglement is verified by the Bell inequality violation for a wide range of feasible parameters, showing the potential of the entangled source for realizing quantum state transfer between microwave and optical frequencies.

In Part A: We will propose the experimental scheme for entanglement generation and detection.

*LPS/ARO, (AFOSR) MURI

Presenters

  • Xu Han

    • Yale Univ
    • Electrical Engineering, Yale University
    • Department of Electrical Engineering, Yale University

Authors

  • Xu Han

    • Yale Univ
    • Electrical Engineering, Yale University
    • Department of Electrical Engineering, Yale University

  • Changchun Zhong

    • Applied Physics, Yale University

  • Mengzhen Zhang

    • Yale Univ
    • Applied Physics, Yale University

  • Chang-Ling Zou

    • University of Science and Technology of China
    • Key Laboratory of Quantum Information, University of Science and Technology of China
    • Yale University
    • USTC

  • Wei Fu

    • Yale Univ
    • Electrical Engineering, Yale University
    • Department of Electrical Engineering, Yale University
    • Yale University

  • Mingrui Xu

    • Yale Univ
    • Electrical Engineering, Yale University
    • Department of Electrical Engineering, Yale University

  • Zhixin Wang

    • Yale Univ
    • Applied Physics, Yale University
    • Department of Applied Physics, Yale University

  • Shyam Shankar

    • Yale Univ
    • Applied Physics, Yale University
    • Department of Applied Physics, Yale University

  • Michel H. Devoret

    • Yale Univ
    • Applied Physics, Yale University
    • Department of Applied Physics, Yale University
    • Department of Applied Physics, Yale University, New Haven, Connecticut 06511, USA

  • Hong X Tang

    • Electrical Engineering, Yale University
    • Yale Univ
    • Department of Electrical Engineering, Yale University
    • Yale University

  • Liang Jiang

    • Yale Univ
    • Applied Physics, Yale University
    • Departments of Physics and Applied Physics, Yale University
    • Departments of Applied Physics and Physics, Yale Univ
    • Department of Applied Physics and Physics, Yale University