Gaussian Entanglement Measure: Applications to Multipartite Entanglement
of Graph States and Bosonic Field Theory
- URL: http://arxiv.org/abs/2401.17938v2
- Date: Wed, 13 Mar 2024 14:40:21 GMT
- Title: Gaussian Entanglement Measure: Applications to Multipartite Entanglement
of Graph States and Bosonic Field Theory
- Authors: Matteo Gori, Matthieu Sarkis, Alexandre Tkatchenko
- Abstract summary: An entanglement measure based on the Fubini-Study metric has been recently introduced by Cocchiarella and co-workers.
We present the Gaussian Entanglement Measure (GEM), a generalization of geometric entanglement measure for multimode Gaussian states.
By providing a computable multipartite entanglement measure for systems with a large number of degrees of freedom, we show that our definition can be used to obtain insights into a free bosonic field theory.
- Score: 50.24983453990065
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Computationally feasible multipartite entanglement measures are needed to
advance our understanding of complex quantum systems. An entanglement measure
based on the Fubini-Study metric has been recently introduced by Cocchiarella
and co-workers, showing several advantages over existing methods, including
ease of computation, a deep geometrical interpretation, and applicability to
multipartite entanglement. Here, we present the Gaussian Entanglement Measure
(GEM), a generalization of geometric entanglement measure for multimode
Gaussian states, based on the purity of fragments of the whole systems. Our
analysis includes the application of GEM to a two-mode Gaussian state coupled
through a combined beamsplitter and a squeezing transformation. Additionally,
we explore 3-mode and 4-mode graph states, where each vertex represents a
bosonic mode, and each edge represents a quadratic transformation for various
graph topologies. Interestingly, the ratio of the geometric entanglement
measures for graph states with different topologies naturally captures
properties related to the connectivity of the underlying graphs. Finally, by
providing a computable multipartite entanglement measure for systems with a
large number of degrees of freedom, we show that our definition can be used to
obtain insights into a free bosonic field theory on $\mathbb R_t\times S^1$,
going beyond the standard bipartite entanglement entropy approach between
different regions of spacetime. The results presented herein suggest how the
GEM paves the way for using quantum information-theoretical tools to study the
topological properties of the space on which a quantum field theory is defined.
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