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Continuous time-nonlocal measurements enable quantum state transfer, establishing relations between past and future quantum system states. This method allows for perfect state transfer via teleportation or direct transmission between oscillators.

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Area of Science:

  • Quantum mechanics
  • Quantum information science
  • Quantum optics

Background:

  • Quantum systems' future and past states can be predicted or retrodicted using regular measurements.
  • Time-nonlocal measurements introduce uncertainty but can link past and future quantum states.

Purpose of the Study:

  • To demonstrate the use of continuous time-nonlocal measurements for quantum state transfer.
  • To explore state transfer via teleportation and direct transmission.
  • To identify strategies for perfect state transfer in linear oscillator-field interactions.

Main Methods:

  • Utilizing continuous time-nonlocal measurements on quantum systems.
  • Analyzing interactions between two oscillators and traveling fields.
  • Developing analytical strategies for state transfer.

Main Results:

  • Continuous time-nonlocal measurements can achieve quantum state transfer.
  • Perfect state transfer is achievable via teleportation or direct transmission.
  • Strategies for perfect state transfer were identified for various linear oscillator-field interactions.

Conclusions:

  • Time-nonlocal measurements offer a novel approach to quantum state transfer.
  • The identified strategies enable robust state transfer beyond standard interaction types.