Optimal fidelity for quantum teleportation protocol of an arbitrary qubit state affected by amplitude-damping noise: causes and results

The improvement of the average fidelity of the quantum teleportation protocol of an arbitrary qubit state has been researched. The initial quantum channel is chosen as the non-maximally entangled state, and this state depends on a free parameter. One qubit of this quantum channel is influenced by th...

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Bibliographic Details
Published in:Quantum information processing 2019-11, Vol.18 (11), p.1-18, Article 340
Main Author: Van Hop, Nguyen
Format: Article
Language:English
Subjects:
Accuracy
Amplitudes
Damping
Data Structures and Information Theory
Entangled states
Markov processes
Mathematical Physics
Noise
Optimization
Parameters
Physics
Physics and Astronomy
Quantum Computing
Quantum entanglement
Quantum Information Technology
Quantum mechanics
Quantum Physics
Quantum teleportation
Qubits (quantum computing)
Spintronics
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Summary:The improvement of the average fidelity of the quantum teleportation protocol of an arbitrary qubit state has been researched. The initial quantum channel is chosen as the non-maximally entangled state, and this state depends on a free parameter. One qubit of this quantum channel is influenced by the amplitude-damping noise environment in the Markovian regime or the non-Markovian regime. The average fidelity is enhanced efficiently through the appropriately selected free parameter of the initial quantum channel. The optimization could not be attributed to the probability as well as the noise environment that makes the initial quantum channel becomes the closest quantum channel to the maximally entangled one. Our study shows that the average fidelity is enhanced as the quantum entanglement of the initial quantum channel is harmoniously redistributed into the entanglement of quantum channel influenced by the noise environment and the entanglement between each of the qubits in this quantum channel and the noise environment.
ISSN:1570-0755
1573-1332
DOI:10.1007/s11128-019-2455-7