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XM Xiu (2008)
Quantum teleportation schemes of an N-Particle state via three-particle general W statesCommun. Theor. Phys., 49
LF Han (2007)
Efficient multiparty-to-multiparty quantum secret sharing via continuous variable operationsChin. Phys. Lett., 24
MY Wang (2009)
111Eur. Phys. J. D, 54
FG Deng (2005)
Bidirectional quantum secret sharing and secret splitting with polarized single photonsPhys. Lett. A, 337
YS Zhang (2005)
062331Phys. Rev. A, 71
AM Wang (2007)
Remote implementations of partially unknown quantum operations of multiqubitsPhys. Rev. A, 74
GL Long, XS Liu (2002)
Theoretically efficient high-capacity quantum-key-distribution schemePhys. Rev. A, 65
GL Long (2002)
032302Phys. Rev. A, 65
CH Bennett, G Brassard, C Crépeau (1993)
Teleporting an unknown quantum state via dual classical and Einstein-Podolsky-Rosen channelsPhys. Rev. Lett., 70
AM Wang (2007)
Combined and controlled remote implementations of partially unknown quantum operations of multiqubits using Greenberger-Horne-Zeilinger statesPhys. Rev. A, 75
ZJ Zhang (2005)
Improving the security of multiparty quantum secret sharing against Trojan horse attackPhys. Rev. A, 72
FG Deng (2005)
Multiparty quantum-state sharing of an arbitrary two-particle state with Einstein-Podolsky-Rosen pairsPhys. Rev. A, 72
YB Zhan (2004)
Teleportation of N-particle entangled W state via entanglement swappingChin. Phys., 13
SF Huelga (2001)
042303Phys. Rev. A, 63
ZJ Zhang (2005)
022303Phys. Rev. A, 72
CY Cheung, ZJ Zhang (2009)
Criterion for faithful teleportation with an arbitrary multiparticle channelPhys. Rev. A, 80
J. Yang (2009)
Teleporting and splitting arbitrary single-qubit information using a class of three-qubit W statesInt. J. Quantum Inf., 7
AM Wang (2007)
032317Phys. Rev. A, 74
T Gao, FL Yan, YC Li (2008)
Optimal controlled teleportationEuro. Phys. Lett., 84
S Muralidharan (2008)
062333Phys. Rev. A, 78
ZJ Zhang, ZX Man (2005)
Multiparty quantum secret sharing of classical messages based on entanglement swappingPhys. Rev. A, 72
AM Wang, NB Zhao (2008)
Local implementation of nonlocal operations with block formsPhys. Rev. A, 79
FL Yan (2003)
297Phys. Lett. A, 316
M Hillery (1999)
1829Phys. Rev. A, 59
SF Huelga (2002)
042316Phys. Rev. A, 65
H Yuan (2008)
Optimizing resource consumption, operation complexity and efficiency in quantum-state sharingJ. Phys. B, 41
ZJ Zhang, CY Cheung (2011)
Shared quantum remote control: quantum operation sharingJ. Phys. B, 44
LF Han, YM Liu, SH Shi, ZJ Zhang (2007)
Improving the security of a quantum secret sharing protocol between multiparty and multiparty without entanglementPhys. Lett. A, 361
S Muralidharan (2011)
1082Opt. Commun., 284
CY Cheung (2009)
022327Phys. Rev. A, 80
HJ Cao, HS Song (2006)
Quantum secure direct communication with W stateChin. Phys. Lett., 23
S Muralidharan, S Jain, PK Panigrahi (2011)
Splitting of quantum information using N-qubit linear cluster statesOpt. Commun., 284
ZJ Zhang (2005)
Multiparty quantum secret sharing of secure direct communicationPhys. Lett. A, 342
AM Wang (2008)
014305Phys. Rev. A, 79
B.L. Ye (2013)
Remotely sharing single-qubit operation with five-qubit genuine stateChin. Phys. Lett., 30
W Dür (2000)
Three qubits can be entangled in two inequivalent waysPhys. Rev. A, 62
HJ Cao, HS Song (2006)
Quantum secure direct communication scheme using a W state and teleportationPhys. Scr., 74
AM Wang (2007)
062317Phys. Rev. A, 76
FL Yan, D Wang (2003)
Probabilistic and controlled teleportation of unknown quantum statesPhys. Lett. A, 316
D Bouwmeester (1997)
Experimental quantum teleportationNature, 390
CH Bennett (1993)
1895Phys. Rev. Lett., 70
ZJ Zhang (2011)
165508J. Phys. B, 44
ZJ Zhang, Y Li, ZX Man (2005)
Multiparty quantum secret sharingPhys. Rev. A, 71
J Joo (2003)
Quantum teleportation via a W stateNew J. Phys., 5
LF Han (2008)
Remote preparation of a class of three-qubit statesOpt. Commun., 281
AM Wang, NB Zhao (2007)
Hybrid protocol of remote implementations of quantum operationsPhys. Rev. A, 76
GL Long, FG Deng, XS Liu (2003)
Two-step quantum direct communication protocol using the Einstein-Podolsky-Rosen pair blockPhys. Rev. A, 68
SF Huelga (2001)
Quantum remote control: teleportation of unitary operationsPhys. Rev. A, 63
MY Wang, FL Yan (2009)
Chain teleportation via partially entangled statesEur. Phys. J. D, 54
D Bouwmeester (1997)
575Nature, 390
S Muralidharan, PK Panigrahi (2008)
Quantum-information splitting using multipartite cluster statesPhys. Rev. A, 78
SF Huelga (2002)
Remote control of restricted sets of operations: teleportation of anglesPhys. Rev. A, 65
AM Wang (2007)
062323Phys. Rev. A, 75
M Hillery, V Bužk (1999)
Quantum secret sharingPhys. Rev. A, 59
GL Long (2003)
042317Phys. Rev. A, 68
T Gao (2008)
50001Euro. Phys. Lett., 84
BS Shi, A Tomita (2002)
Teleportation of an unknown state by W statePhys. Lett. A, 296
ZJ Zhang (2005)
044301Phys. Rev. A, 71
YS Zhang, MY Ye, GC Guo (2005)
Conditions for optimal construction of two-qubit nonlocal gatesPhys. Rev. A, 71
FG Deng (2005)
044302Phys. Rev. A, 72
Two tripartite schemes for sharing a single-qubit operation on a remote target state are proposed with symmetric and asymmetric W states, respectively. They are treated and compared from the aspects of quantum resource consumption, operation complexity, classical resource consumption, success probability and efficiency. It is found that the first scheme is better than the second one. In particular, the sharing can be achieved probabilistically with the first scheme while deterministically with the second one.
Quantum Information Processing – Springer Journals
Published: Feb 22, 2013
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