Deterministic entanglement swapping of W states

• URL: http://arxiv.org/abs/2407.03603v1
• Date: Thu, 4 Jul 2024 03:27:12 GMT
• Title: Deterministic entanglement swapping of W states
• Authors: Sajede Harraz, Yueyan Wang, Shuang Cong,
• Abstract summary: We propose a deterministic entanglement swapping protocol for generating a shared three-qubit W state between two remote parties. We present a detailed quantum circuit design, implemented using the Qiskit simulator, that outlines the preparation of W states and the execution of joint measurements. We demonstrate the effectiveness of our proposed protocol, offering a practical solution for high-fidelity W state generation in real-world quantum communication scenarios.
• Score: 0.3277163122167434
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: In this paper, we propose a deterministic entanglement swapping protocol for generating a shared three-qubit W state between two remote parties. Our method offers a reliable alternative to existing probabilistic protocols for W state entanglement swapping, which is crucial for various quantum information processing tasks. We present a detailed quantum circuit design, implemented using the Qiskit simulator, that outlines the preparation of W states and the execution of joint measurements required for the entanglement swapping process. Furthermore, we analyze the effects of imperfect operations and noisy communication channels on the fidelity of the resulting shared W state. To address these challenges, we introduce a weak measurement-based purification method that enhances fidelity in the presence of amplitude damping. Through mathematical analysis and Qiskit simulations, we demonstrate the effectiveness of our proposed protocol, offering a practical solution for high-fidelity W state generation in real-world quantum communication scenarios.

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