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Main Authors: Yan, Xiaokun, Wang, Zhihai, Zhang, Kun, Wang, Jin
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.05743
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author Yan, Xiaokun
Wang, Zhihai
Zhang, Kun
Wang, Jin
author_facet Yan, Xiaokun
Wang, Zhihai
Zhang, Kun
Wang, Jin
contents Quantum teleportation, a fundamental protocol in quantum information science, enables the transfer of quantum states through entangled particle pairs and classical communication channels. While ideal quantum teleportation requires maximally entangled states as resources, real-world implementations inevitably face environmental noise and decoherence effects. In this work, we investigate quantum teleportation in non-equilibrium environments with different temperatures or chemical potentials. We apply the Bloch-Redfield equation to characterize the non-equilibrium dynamics. In both bosonic and fermionic setups, the fidelity can be enhanced beyond the equilibrium values. Under specific non-equilibrium conditions, the fidelities of all input states are identical. We call it teleportation with a fixed-point fidelity. Notably, at the fixed-point, fidelity can also be enhanced by combining the two detuned qubits and non-equilibrium environments. These findings provide important guidance for implementing quantum communication protocols in realistic environments, while the fixed-point mechanism offers a promising pathway toward simplifying practical quantum teleportation schemes.
format Preprint
id arxiv_https___arxiv_org_abs_2505_05743
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quantum Teleportation in Non-equilibrium Environments and Fixed-point Fidelity
Yan, Xiaokun
Wang, Zhihai
Zhang, Kun
Wang, Jin
Quantum Physics
Quantum teleportation, a fundamental protocol in quantum information science, enables the transfer of quantum states through entangled particle pairs and classical communication channels. While ideal quantum teleportation requires maximally entangled states as resources, real-world implementations inevitably face environmental noise and decoherence effects. In this work, we investigate quantum teleportation in non-equilibrium environments with different temperatures or chemical potentials. We apply the Bloch-Redfield equation to characterize the non-equilibrium dynamics. In both bosonic and fermionic setups, the fidelity can be enhanced beyond the equilibrium values. Under specific non-equilibrium conditions, the fidelities of all input states are identical. We call it teleportation with a fixed-point fidelity. Notably, at the fixed-point, fidelity can also be enhanced by combining the two detuned qubits and non-equilibrium environments. These findings provide important guidance for implementing quantum communication protocols in realistic environments, while the fixed-point mechanism offers a promising pathway toward simplifying practical quantum teleportation schemes.
title Quantum Teleportation in Non-equilibrium Environments and Fixed-point Fidelity
topic Quantum Physics
url https://arxiv.org/abs/2505.05743