Bipartite Relativistic Quantum Information: An Effective Field Theory Approach to Entanglement Harvesting, Quantum Discord, and Nonlocality

The provided text outlines an Effective Field Theory (EFT) approach to studying Relativistic Quantum Information (RQI) in the simplified scenario of static Unruh-DeWitt (UDW) detectors. To incorporate the dynamics of UDW detectors and delve into more intricate RQI tasks, several extensions to this framework can be considered: Post-Newtonian (PN) Expansion: As briefly mentioned in the text, going beyond the leading-order Coulombic interaction of the 0PN EFT action (Eq. 2.2) is crucial for studying dynamic UDW detectors. By incorporating higher-order terms in the velocity expansion, we obtain a PN EFT that captures the effects of motion. The 1PN order, for instance, would introduce velocity-dependent potentials and allow for the study of entanglement harvesting and other RQI tasks in scenarios involving moving detectors. Radiation Reaction: Incorporating radiation reaction into the EFT framework is essential for a complete description of dynamic systems. As UDW detectors move and interact, they emit radiation that backreacts on their dynamics. This backreaction can be systematically included in the EFT by considering half-integral PN orders. Including radiation reaction would enable the investigation of its impact on entanglement harvesting, decoherence, and other RQI protocols. Time-Dependent Backgrounds: The text focuses on a static black hole background. Extending the EFT framework to time-dependent backgrounds, such as evaporating black holes or cosmological spacetimes, would open avenues for exploring RQI in more realistic and dynamic settings. This would involve incorporating the time dependence into the mode functions of the mediator field and the subsequent derivation of the effective action. Beyond Entanglement Harvesting: While entanglement harvesting serves as a primary example, the EFT framework can be applied to a broader range of RQI tasks. These include: Quantum Teleportation: Investigating the fidelity of quantum teleportation protocols in curved spacetime and the influence of the black hole's gravitational field. Quantum Communication: Studying the capacity and fidelity of quantum communication channels in relativistic settings, considering the effects of spacetime curvature and horizons. Quantum Metrology: Exploring the potential for enhanced precision in quantum metrology tasks by exploiting relativistic effects and the properties of quantum fields in curved spacetime. By implementing these extensions, the EFT framework can provide a powerful tool for investigating the interplay between gravity, quantum information, and relativistic phenomena in a wide range of scenarios.

The text hints at a potential discrepancy in the interpretation of locality when comparing Quantum Field Theory (QFT) and Relativistic Quantum Information (RQI). While the EFT approach seemingly employs a "classical" environment, it still predicts entanglement harvesting, a phenomenon typically associated with non-local quantum correlations. This observation could indeed point towards a deeper principle governing the relationship between gravity and quantum information. Here's a breakdown of the potential implications: Contextual Locality: The discrepancy might suggest that locality in QFT and RQI operates under different contextual frameworks. In QFT, locality is often defined through the commutation of field operators at spacelike separations. However, RQI introduces the concept of entanglement harvesting, where entanglement can be generated between spacelike separated detectors due to their interaction with a shared quantum field. This suggests that the presence of entanglement, and hence the manifestation of non-locality, might be observer-dependent or context-dependent in the presence of gravity. Quantum Information as a Probe for Gravity: The observed discrepancy could imply that quantum information theory provides a unique lens through which to understand the non-local features of gravity. Entanglement, a fundamental concept in quantum information, might serve as a sensitive probe for exploring the subtle ways in which gravity departs from classical notions of locality. Emergent Spacetime from Quantum Entanglement: Some theoretical frameworks propose that spacetime itself might be an emergent phenomenon arising from the entanglement structure of underlying quantum degrees of freedom. The observed discrepancy in locality could be a manifestation of this deeper connection, where the entanglement harvested by UDW detectors reflects the underlying entanglement structure of spacetime. Further investigation into these discrepancies could lead to a more profound understanding of the interplay between gravity and quantum information. It might reveal novel principles governing the emergence of spacetime, the nature of quantum correlations in gravitational settings, and the limits of classical notions of locality.

The text's observation that a seemingly "classical" environment in EFT can still result in entanglement harvesting does raise intriguing questions about the traditional understanding of classicality within quantum information theory. Here's a nuanced perspective on this challenge: Classicality in EFT: It's crucial to recognize that the term "classical" in the context of EFT carries a specific meaning. It refers to the fact that the EFT approach integrates out the high-energy degrees of freedom of the mediator field, effectively treating it as a classical background field. However, this classical background field still inherits crucial quantum properties from the underlying quantum field theory, particularly the thermal nature of the black hole's environment. Entanglement Harvesting and Non-Classical Correlations: Entanglement harvesting fundamentally relies on the non-classical correlations present in the vacuum state of the quantum field. Even though the EFT treats the mediator field classically, it still captures these non-classical correlations through the spectral density of the blackbody and the resulting effective interactions between the UDW detectors. Redefining Classicality: This observation suggests that the traditional dichotomy between classical and quantum environments might be too simplistic in the context of relativistic quantum information. The EFT approach highlights that even seemingly classical environments can exhibit non-classical features when gravity is involved. This calls for a more nuanced understanding of classicality, one that considers the potential for non-classical correlations to persist even in systems where certain degrees of freedom are treated classically. LOCC vs. "Classical" EFT Environment: The text correctly points out that the "classical" environment in EFT differs significantly from Local Operations and Classical Communication (LOCC) in quantum information tasks. LOCC operations are fundamentally incapable of creating entanglement, while the "classical" EFT environment can lead to entanglement harvesting. This distinction arises because the EFT environment still encodes non-classical correlations inherited from the underlying quantum field theory, while LOCC operations are strictly limited to local quantum operations and classical communication. In conclusion, the observation of entanglement harvesting in a "classical" EFT environment prompts a reevaluation of classicality in relativistic quantum information. It suggests that non-classical correlations can persist in seemingly classical settings when gravity is involved, highlighting the need for a more nuanced understanding of the classical-quantum boundary in these scenarios.