Abstract
We examine in (2+1)-dimensional anti-de Sitter (AdS) space the phenomena of entanglement harvesting — the process in which a pair of detectors (two-level atoms) extract entanglement from a quantum field through local interactions with the field. We begin by reviewing the Unruh-DeWitt detector and its interaction with a real scalar field in the vacuum state, as well as the entanglement harvesting protocol in general. We then examine how the entanglement harvested by a pair of such detectors depends on their spacetime trajectory, separation, spacetime curvature, and boundary conditions satisfied by the field. The harvested entanglement is interpreted as an indicator of field entanglement between the localized regions where the detectors interact with the field, and thus this investigation allows us to probe indirectly the entanglement structure of the AdS vacuum. We find an island of separability for specific values of the detectors’ energy gap and separation at intermediate values of the AdS length for which entanglement harvesting is not possible; an analogous phenomena is observed in AdS4, to which we compare and contrast our results. In the process we examine how the transition probability of a single detector, as a proxy for local fluctuations of the field, depends on spacetime curvature, its location in AdS space, and boundary conditions satisfied by the field.
Highlights
Itself, allowing one to probe properties of the field such as local fluctuations and their correlations
In the process we examine how the transition probability of a single detector, as a proxy for local fluctuations of the field, depends on spacetime curvature, its location in anti-de Sitter (AdS) space, and boundary conditions satisfied by the field
In this way the entanglement harvesting protocol can be used to probe the entanglement structure of the vacuum state of a quantum field theory
Summary
We introduce the Unruh-DeWitt detector as a simplified model of a two-level atom interacting locally with a quantum field. We review the derivation of the joint state of two such detectors after their interaction with the field has ceased, stating explicitly the matrix elements appearing in this state to leading order in the interaction strength in terms of the vacuum Wightman function. We introduce scalar field theory on (2+1)-AdS space, stating explicitly the associated vacuum Wightman function
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