Quantum information with continuous variables

Braunstein, Samuel L.; Pati, Arun Kumar

doi:10.1103/revmodphys.77.513

Cited by 3,339 publications

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References 267 publications

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“…Apart from two qubit systems, various attempts have been made to produce entanglement in more complex systems. An extensive research have been done on generation of multipartite continuous variable entangled states of atomic ensembles form multi-mode squeezed light [50][51][52][53]. The reason for using atomic ensembles is twofold.…”

Section: Introductionmentioning

confidence: 99%

Quantum entanglement and disentanglement of multi-atom systems

Ficek

2009

Front. Phys. China

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We present a review of recent research on quantum entanglement, with special emphasis on entanglement between single atoms, processing of an encoded entanglement and its temporary evolution. Analysis based on the density matrix formalism are described. We give a simple description of the entangling procedure and explore the role of the environment in creation of entanglement and in disentanglement of atomic systems. A particular process we will focus on is spontaneous emission, usually recognized as an irreversible loss of information and entanglement encoded in the internal states of the system. We illustrate some certain circumstances where this irreversible process can in fact induce entanglement between separated systems. We also show how spontaneous emission reveals a competition between the Bell states of a two qubit system that leads to the recently discovered "sudden" features in the temporal evolution of entanglement. An another problem illustrated in details is a deterministic preparation of atoms and atomic ensembles in long-lived stationary squeezed states and entangled cluster states. We then determine how to trigger the evolution of the stable entanglement and also address the issue of a steered evolution of entanglement between desired pairs of qubits that can be achieved simply by varying the parameters of a given system.

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Section: Introductionmentioning

confidence: 99%

Quantum entanglement and disentanglement of multi-atom systems

Ficek

2009

Front. Phys. China

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“…Quantum communications concern the study of quantum channels that also use continuous alphabets [1]. These can be modeled by bosonic field modes whose phase space quadratures enable for continuous variable encoding/decoding.…”

Section: Introductionmentioning

confidence: 99%

“…Since we deal with Gaussian states, it turns useful to work with Wigner distribution functions [1]. Let q k , p k be the quadrature variables ofâ k , i.e.…”

Section: Introductionmentioning

confidence: 99%

“…is the single kmode displacement operator, corresponding to the complex number µ k andŜ a (r) = exp 1 2 r â † 1â † 2 −â 1â2 denotes the two-mode squeeze operator [1], with r the entanglement parameter between the two inputs (r = 0 refers to input product states). Let us write the input (1) as a density operator…”

Section: Introductionmentioning

confidence: 99%

“…These can be modeled by bosonic field modes whose phase space quadratures enable for continuous variable encoding/decoding. Lossy bosonic channel, which consists of a collection of bosonic modes that lose energy en route from the transmitter to the receiver, belongs to the class of Gaussian channels which provide a fertile testing ground for the general theory of quantum channels' capacities [2] and are easy to implement experimentally with high accuracy level (beam splitters or squeezers are examples of Gaussian operations) [1]. Hence, the increasing attention devoted to channels with memory effects, where the noise may be strongly correlated between uses of the channel, has been extended to bosonic channels [3].…”

Section: Introductionmentioning

confidence: 99%

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