Entanglement distribution based on quantum walk in arbitrary quantum networks

• URL: http://arxiv.org/abs/2407.04338v2
• Date: Thu, 09 Jan 2025 15:22:22 GMT
• Title: Entanglement distribution based on quantum walk in arbitrary quantum networks
• Authors: Tianen Chen, Yun Shang, Chitong Chen, Heng Fan,
• Abstract summary: We provide a quantum fractal network based on $d$-dimensional GHZ states. Compared with the continuous quantum walk on the Sierpinski gasket, the quantum walk on the new fractal network spreads more widely within the same time frame. Our study can serve as a building block for constructing large and complex quantum networks.
• Score: 6.37705397840332
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• Abstract: In large-scale quantum networks, quantum repeaters provide an efficient method to distribute entangled states among selected nodes for realizing long-distance and complicated quantum communications. However, extending quantum repeater protocols to high-dimensional quantum states in existing experiments is not easy. Owing to the feasible physical implementations of quantum walks, we proposed various basic modules applicable to quantum repeaters for distributing high-dimensional entangled states via quantum walks, including $d$-dimensional Bell states and multi-particle $d$-dimensional GHZ states. Furthermore, based on the above schemes, we provided a high-dimensional entanglement distribution scheme for arbitrary quantum tree networks. By searching for a Steiner tree in a quantum network, we can achieve high-dimensional entanglement distributions over an arbitrary quantum network. We constructed a quantum fractal network based on $d$-dimensional GHZ states and analyzed the quantum transport properties of continuous quantum walks in the network. Compared with the continuous quantum walk on the Sierpinski gasket, the quantum walk on the new fractal network spreads more widely within the same time frame. Finally, we conducted five experiments to implement various basic modules of 2-party or 3-party entanglement distribution schemes in a superconducting quantum processor. Our study can serve as a building block for constructing large and complex quantum networks.

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