Entangled Pure State Transformations via Local Operations Assisted by Finitely Many Rounds of Classical Communication

C. Spee; J. I. De Vicente; D. Sauerwein; B. Kraus

doi:10.1103/PhysRevLett.118.040503

Entangled Pure State Transformations via Local Operations Assisted by Finitely Many Rounds of Classical Communication

C. Spee, J. I. De Vicente, D. Sauerwein, B. Kraus

Research output: Contribution to journal › Article › peer-review

21 Scopus citations

Abstract

We consider generic pure n-qubit states and a general class of pure states of arbitrary dimensions and arbitrarily many subsystems. We characterize those states which can be reached from some other state via local operations assisted by finitely many rounds of classical communication (LOCCN). For n qubits with n>3, we show that this set of states is of measure zero, which implies that the maximally entangled set is generically of full measure if restricted to the practical scenario of LOCCN. Moreover, we identify a class of states for which any LOCCN protocol can be realized via a concatenation of deterministic steps. We show, however, that in general there exist state transformations which require a probabilistic step within the protocol, which highlights the difference between bipartite and multipartite LOCC.

Original language	English
Article number	040503
Journal	Physical Review Letters
Volume	118
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevLett.118.040503
State	Published - 27 Jan 2017
Externally published	Yes

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abstract = "We consider generic pure n-qubit states and a general class of pure states of arbitrary dimensions and arbitrarily many subsystems. We characterize those states which can be reached from some other state via local operations assisted by finitely many rounds of classical communication (LOCCN). For n qubits with n>3, we show that this set of states is of measure zero, which implies that the maximally entangled set is generically of full measure if restricted to the practical scenario of LOCCN. Moreover, we identify a class of states for which any LOCCN protocol can be realized via a concatenation of deterministic steps. We show, however, that in general there exist state transformations which require a probabilistic step within the protocol, which highlights the difference between bipartite and multipartite LOCC.",

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AB - We consider generic pure n-qubit states and a general class of pure states of arbitrary dimensions and arbitrarily many subsystems. We characterize those states which can be reached from some other state via local operations assisted by finitely many rounds of classical communication (LOCCN). For n qubits with n>3, we show that this set of states is of measure zero, which implies that the maximally entangled set is generically of full measure if restricted to the practical scenario of LOCCN. Moreover, we identify a class of states for which any LOCCN protocol can be realized via a concatenation of deterministic steps. We show, however, that in general there exist state transformations which require a probabilistic step within the protocol, which highlights the difference between bipartite and multipartite LOCC.

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Entangled Pure State Transformations via Local Operations Assisted by Finitely Many Rounds of Classical Communication

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