Entangled detectors nonperturbatively harvest mutual information
Kensuke Gallock‐Yoshimura, Robert B. Mann
Abstract
We investigate how entangled inertial Unruh-DeWitt detectors are affected by interaction with a quantum field using a nonperturbative method. Inertial detectors in a ($3+1$)-dimensional Minkowski spacetime with instantaneous switching ($\ensuremath{\delta}$-switching) experience degradation of their initial entanglement as their coupling strength with a scalar field increases. Somewhat surprisingly, initially separable or weakly entangled detectors can extract mutual information from the vacuum. We also find that entanglement degradation is not reduced if communication via the field is possible; rather this only changes the manner in which entanglement is degraded.
Topics & Concepts
Quantum entanglementPhysicsUnruh effectMinkowski spaceDetectorInertial frame of referenceScalar fieldQuantum mechanicsMutual informationQuantum field theoryField (mathematics)QuantumQuantum electrodynamicsOpticsMathematicsStatisticsPure mathematicsQuantum Electrodynamics and Casimir EffectQuantum Mechanics and ApplicationsThermal Radiation and Cooling Technologies