Related papers: Bipartite Relativistic Quantum Information from Effective Field Theory Approach with Implications to Contextual Meanings of Locality and Quantumness

Bipartite Relativistic Quantum Information from Effective Field Theory Approach with Implications to Contextual Meanings of Locality and Quantumness

URL: http://arxiv.org/abs/2411.09409v1
Date: Thu, 14 Nov 2024 12:56:45 GMT
Title: Bipartite Relativistic Quantum Information from Effective Field Theory Approach with Implications to Contextual Meanings of Locality and Quantumness
Authors: Feng-Li Lin, Sayid Mondal,
Abstract summary: We study the relativistic quantum information (RQI) of two static UDW-charged qubits with or without a black hole. The RQI of the quantum state of the mediator field can be probed by the reduced final states of UDW detectors. We find that QFT and RQI agree on quantumness based on different physical reasons but may not agree on locality.
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Abstract: In a recent work \cite{biggs2024comparing}, the effective field theory (EFT) is adopted to consider the quantum decoherence of a near-horizon Unrhu-DeWitt (UDW) charged qubit in a macroscopic cat state. We generalize this EFT approach to study the relativistic quantum information (RQI) of two static UDW-charged qubits with or without a black hole. This EFT is obtained by integrating out a massless mediator field, yielding the direct Coulombic interactions among intrinsic multipole moments of UDW detectors and the induced one on the black hole. The RQI of the quantum state of the mediator field can be probed by the reduced final states of UDW detectors by tracing out the induced internal states of the black hole. From the reduced final state, we find the patterns of entanglement harvesting agree with the ones obtained by the conventional approach based on master theory. However, the more detailed study suggests that the contextual meanings of (non-)locality may or may not be the same in quantum field theory (QFT) and RQI. To explore the contextual meanings of quantumness and locality more, we also calculate quantum discord and locality bound of the Bell-type experiments, with the former characterizing the non-classical correlations and the latter the (non-)locality in the hidden-variable context of RQI. We find that QFT and RQI agree on quantumness based on different physical reasons but may not agree on locality.

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