Abstract
We investigate two quantum communication protocols of dense coding and teleportation based on two coupled quantum dot molecules under intrinsic decoherence, tunneling rates, and Coulomb coupling interaction. In addition, due to the importance of estimating the initial phase, we monitor the initial quantum phase of the teleportation, which may have information encoded in it, using a family of quantum statistical speeds, especially quantum Fisher information and Hilbert–Schmidt speed. Moreover, we compare the results between single and two-qubit teleportations, such that the superiority of single-qubit teleportation in the current model can be obvious. The assumed scheme’s various parameters help us improve quantum dense coding, teleportation, and phase estimation in the current model. Furthermore, we reveal that the tools discussed in this paper can all provide witnessing non-Markovian dynamics.
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Abbreviations
- LOCC:
-
Local ope rations and classical communication
- QFI:
-
Quantum Fisher information
- HSS:
-
Hilbert–Schmidt speed
- CR:
-
Cramér–Rao
- QSS:
-
Quantum statistical speed
- SQ:
-
Single-qubit teleportation
- TQ:
-
Two-qubit teleportation
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The authors wish to acknowledge the financial support of Urmia University.
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Interpretations and comparison of results and writing of the article were done by SMH. All authors reviewed the manuscript.
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Hosseiny, S.M. Quantum dense coding and teleportation based on two coupled quantum dot molecules influenced by intrinsic decoherence, tunneling rates, and Coulomb coupling interaction. Appl. Phys. B 130, 8 (2024). https://doi.org/10.1007/s00340-023-08130-8
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DOI: https://doi.org/10.1007/s00340-023-08130-8