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Continuous-variable quantum teleportation with vacuum-entangled Rindler modes

Joshua Foo, Timothy C. Ralph

2020Physical review. D/Physical review. D.15 citationsDOIOpen Access PDF

Abstract

We consider a continuous-variable quantum teleportation protocol between a uniformly accelerated sender in the right Rindler wedge, a conformal receiver restricted to the future light cone, and an inertial observer in the Minkowski vacuum. Using a nonperturbative quantum circuit model, the accelerated observer interacts unitarily with the Rindler modes of the field, thereby accessing entanglement of the vacuum as a resource. We find that a Rindler-displaced Minkowski vacuum state prepared and teleported by the accelerated observer appears mixed according to the inertial observer, despite a reduction of the quadrature variances below classical limits. This is a surprising result, since the same state transmitted directly from the accelerated observer appears as a pure coherent state to the inertial observer. The decoherence of the state is caused by an interplay of opposing effects as the acceleration increases: the reduction of vacuum noise in the output state for a stronger entanglement resource, constrained by the amplification of thermal noise due to the presence of Unruh radiation.

Topics & Concepts

Unruh effectPhysicsQuantum entanglementObserver (physics)Quantum decoherenceQuantum mechanicsInertial frame of referenceMinkowski spaceVacuum stateClassical mechanicsQuantumQuantum electrodynamicsQuantum Information and CryptographyQuantum Mechanics and ApplicationsQuantum Electrodynamics and Casimir Effect
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