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References (26)
-
Charles Bennett, S. Wiesner (1992)
Communication via one- and two-particle operators on Einstein-Podolsky-Rosen states.Physical review letters, 69 20
-
Charles Bennett, G. Brassard, C. Crépeau, R. Jozsa, A. Peres, W. Wootters (1993)
Teleporting an unknown quantum state via dual classical and Einstein-Podolsky-Rosen channels.Physical review letters, 70 13
-
A. Borras, A. Plastino, A. Plastino, A. Plastino, J. Batle, C. Zander, M. Casas, A. Plastino (2007)
Multiqubit systems: highly entangled states and entanglement distributionJournal of Physics A: Mathematical and Theoretical, 40
-
S. Choudhury, Sreraman Muralidharan, P. Panigrahi (2008)
Quantum teleportation and state sharing using a genuinely entangled six-qubit stateJournal of Physics A: Mathematical and Theoretical, 42
-
(2005)
Nature -
(2007)
Int. J. Quant. Inf -
(2004)
Phys. Rev. Lett -
(2004)
De), and U. Sen -
M. Hein, J. Eisert, H. Briegel, H. Briegel (2003)
Multiparty entanglement in graph statesPhysical Review A, 69
-
R. Raussendorf, Jim Harrington, Kovid Goyal (2005)
A fault-tolerant one-way quantum computerAnnals of Physics, 321
-
Iain Brown, S. Stepney, A. Sudbery, S. Braunstein (2005)
Searching for highly entangled multi-qubit statesJournal of Physics A, 38
-
(2005)
J. Phys. A -
M. Hein, W. Dür, H. Briegel (2004)
Entanglement properties of multipartite entangled states under the influence of decoherencePhysical Review A, 71
-
H. Briegel, R. Raussendorf (2000)
Persistent entanglement in arrays of interacting particles.Physical review letters, 86 5
-
F. Verstraete, J. Dehaene, B. Moor, H. Verschelde (2001)
Four qubits can be entangled in nine different waysPhysical Review A, 65
-
D. Gottesman (1999)
Theory of quantum secret sharingPhysical Review A, 61
-
M. Hillery, V. Bužek, A. Berthiaume (1998)
Quantum secret sharingPhysical Review A, 59
-
D. Bruß, G. D’Ariano, M. Lewenstein, C. Macchiavello, A. De, U. Sen (2004)
Distributed quantum dense coding.Physical review letters, 93 21
-
D. Schlingemann, R. Werner (2000)
Quantum error-correcting codes associated with graphsArXiv, quant-ph/0012111
-
Charles Bennett, D. DiVincenzo, P. Shor, J. Smolin, B. Terhal, W. Wootters (2000)
Remote state preparation.Physical review letters, 87 7
-
Sreraman Muralidharan, P. Panigrahi (2007)
Perfect teleportation, quantum-state sharing, and superdense coding through a genuinely entangled five-qubit statePhysical Review A, 77
-
(2006)
Quantum Computing Back Action AIP -
Chaoyang Lu, Xiaoqi Zhou, O. Guhne, Wei-bo Gao, Jin Zhang, Zhen-Sheng Yuan, A. Goebel, Tao Yang, Jian-Wei Pan (2006)
Experimental entanglement of six photons in graph statesNature Physics, 3
-
A. Pati (1999)
Minimum classical bit for remote preparation and measurement of a qubitPhysical Review A, 63
-
Muralidharan eprint : quantph/0804.4215 " To be published in Pramana -
W. Dür, G. Vidal, J. Cirac (2000)
Three qubits can be entangled in two inequivalent waysPhysical Review A, 62
- Publisher
- Springer Journals
- Copyright
- Copyright © 2010 by Springer Science+Business Media, LLC
- Subject
- Physics; Mathematics, general; Quantum Physics; Physics, general; Theoretical, Mathematical and Computational Physics; Computer Science, general
- ISSN
- 1570-0755
- eISSN
- 1573-1332
- DOI
- 10.1007/s11128-010-0217-7
- Publisher site
- See Article on Publisher Site
Abstract
The usefulness of the recent experimentally realized six photon cluster state by C. Y. Lu et al. (Nature 3:91, 2007) is investigated for quantum communication protocols like quantum teleportation and quantum information splitting (QIS) and dense coding. We show that the present state can be used for the teleportation of an arbitrary two qubit state deterministically. Later, we devise two distinct protocols for the QIS of an arbitrary two qubit state among two parties. We construct sixteen orthogonal measurement basis on the cluster state, which will lock an arbitrary two qubit state among two parties. The capability of the state for dense coding is investigated and it is shown that one can send five classical bits by sending only three qubits using this state as a shared entangled resource. We finally show that this state can also be utilised in the remote state preparation of an arbitrary two qubit state.
Journal
Quantum Information Processing – Springer Journals
Published: Dec 25, 2010