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Area of Science:

  • Quantum physics
  • General relativity
  • Causality

Background:

  • Classical physics dictates a fixed causal order for events.
  • Quantum mechanics permits superpositions of causal orders, exemplified by the quantum switch.
  • Debate exists on whether optical quantum switches truly represent indefinite causal order or merely simulate it.

Purpose of the Study:

  • To provide a relativistic definition of causal order.
  • To establish a meaningful observable for causal order in both general relativistic and quantum mechanical contexts.
  • To resolve the debate on the validity of optical quantum switch experiments.

Main Methods:

  • Developed a relativistic definition of causal order.
  • Defined an observable for causal order based on operationally defined events.
  • Compared the observable across different quantum switch implementations.

Main Results:

  • The defined observable is meaningful in both general relativistic and quantum mechanical frameworks.
  • The observable does not differentiate between optical quantum switches and hypothetical gravitational quantum switches.
  • This supports the physical reality of indefinite causal order in current experiments.

Conclusions:

  • Optical quantum switch experiments are valid realizations of indefinite causal order.
  • A superposition of spacetime metrics is not strictly required for indefinite causal order.
  • The findings bridge quantum mechanics and general relativity concerning causality.