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Quantum Transduction with Adaptive Control.

Mengzhen Zhang1,2, Chang-Ling Zou1,2,3, Liang Jiang1,2

  • 1Departments of Applied Physics and Physics, Yale University, New Haven, Connecticut 06520, USA.

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|January 30, 2018
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Summary
This summary is machine-generated.

We developed an adaptive quantum transducer protocol that bypasses the need for matching conditions, enabling robust quantum signal conversion. This method facilitates quantum state transfer between microwave and optical modes, crucial for quantum networks.

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Area of Science:

  • Quantum physics
  • Quantum information science
  • Quantum optics

Background:

  • Quantum transducers are essential for connecting different quantum systems in hybrid quantum networks.
  • Current direct mode conversion protocols require strict matching conditions, limiting their practical application.
  • Decoherence and signal loss are major challenges in quantum transduction.

Purpose of the Study:

  • To propose a novel adaptive protocol for quantum transduction that overcomes the limitations of direct conversion.
  • To demonstrate the feasibility of this protocol using only Gaussian operations.
  • To investigate the robustness of the adaptive protocol against common experimental imperfections.

Main Methods:

  • Development of an adaptive quantum transduction protocol.
  • Utilizing Gaussian operations for quantum signal conversion.
  • Theoretical analysis of the protocol's performance under realistic conditions.

Main Results:

  • The adaptive protocol successfully converts quantum signals without requiring matching conditions.
  • The protocol demonstrates robustness against finite squeezing, thermal noise, and homodyne detection imperfections.
  • Successful implementation for quantum state transfer between microwave and optical modes.

Conclusions:

  • The proposed adaptive protocol offers a flexible and practical approach to quantum transduction.
  • This method enhances the potential for building scalable and efficient hybrid quantum networks.
  • The protocol's robustness makes it suitable for near-term quantum technologies.