High-fidelity Generation of Bell and W States in Giant Atom System via Bound State in the Continuum

• URL: http://arxiv.org/abs/2501.04954v2
• Date: Sun, 12 Jan 2025 08:19:07 GMT
• Title: High-fidelity Generation of Bell and W States in Giant Atom System via Bound State in the Continuum
• Authors: Mingzhu Weng, Hongwei Yu, Zhihai Wang,
• Abstract summary: We propose a high-fidelity scheme for generating entangled states in a system of two and three giant atoms coupled to a resonator waveguide. We achieve a fidelity exceeding $98%$ for Bell state generation, overcoming the limitations of conventional decoherence-free interaction mechanisms. Our proposal is feasible for implementation on state-of-the-art solid-state quantum platforms and significantly broadens the applications of giant atoms and waveguide QED system in quantum information processing.
• Score: 2.2940141855172036
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• Abstract: In this paper, we propose a high-fidelity scheme for generating entangled states in a system of two and three giant atoms coupled to the coupled resonator waveguide. Our approach leverages the bound state in the continuum, which is robust against waveguide disorder. Specifically, we achieve a fidelity exceeding $98\%$ for Bell state generation, overcoming the limitations of conventional decoherence-free interaction mechanisms. This scheme can be readily extended to a three-giant-atom system for generating W states. In both the two- and three-atom setups, the maximally entangled states are generated in a short time and remain stable even as time approaches infinity. Our proposal is feasible for implementation on state-of-the-art solid-state quantum platforms and significantly broadens the applications of giant atoms and waveguide QED system in quantum information processing.

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