Quantifying entanglement of two relativistic particles using optimal entanglement witness
Quantum Information Processing
Generation and degree of entanglement in a relativistic formulation
Quantum Information & Computation
Einstein-Podolsky-Rosen correlation seen from moving observers
Quantum Information & Computation
Quantum communication protocols using the vacuum
Quantum Information & Computation
Quantum information channels in curved spacetime
CiE'11 Proceedings of the 7th conference on Models of computation in context: computability in Europe
Entangled spin states in geodesic motion around massive body
Quantum Information Processing
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We study the transformation of maximally entangled states under the action of Lorentz transformations in a fully relativistic setting. By explicit calculation of the Wigner rotation, we describe the relativistic analog of the Bell states as viewed from two inertial frames moving with constant velocity with respect to each other. Though the finite dimensional matrices describing the Lorentz transformations are non-unitary, each single particle state of the entangled pair undergoes an effective, momentum dependent, local unitary rotation, thereby preserving the entanglement fidelity of the bipartite state. The details of how these unitary transformations are manifested are explicitly worked out for the Bell states comprised of massive spin 1/2 particles and massless photon polarizations. The relevance of this work to non-inertial frames is briefly discussed.