Fast quantum state transfer and entanglement preparation in strongly coupled bosonic systems

• URL: http://arxiv.org/abs/2308.05511v2
• Date: Mon, 30 Oct 2023 03:26:11 GMT
• Title: Fast quantum state transfer and entanglement preparation in strongly coupled bosonic systems
• Authors: Yilun Xu, Daoquan Zhu, Feng-Xiao Sun, Qiongyi He, Wei Zhang
• Abstract summary: We propose a novel scheme to implement high-fidelity quantum state transfer (QST) and entanglement preparation (EP) with high speed. In the QST tasks, we consider several typical quantum states and demonstrate that this method is robust against thermal noise and imperfections of experimental sequence. In the EP tasks, the scheme is successfully implemented for the preparation of Bell states and W-type states, within a shortest preparation time.
• Score: 10.14685261482056
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Continuous U(1) gauge symmetry, which guarantees the conservation of the total excitations in linear bosonic systems, will be broken when it comes to the strong-coupling regime where the rotation wave approximation (RWA) fails. Here we develop analytic solutions for multi-mode bosonic systems with XX-type couplings beyond RWA, and proposed a novel scheme to implement high-fidelity quantum state transfer (QST) and entanglement preparation (EP) with high speed. The scheme can be realized with designated coupling strength and pulse duration with which the excitation number keeps unchanged regardless of the breakdown of the global U(1) symmetry. In the QST tasks, we consider several typical quantum states and demonstrate that this method is robust against thermal noise and imperfections of experimental sequence. In the EP tasks, the scheme is successfully implemented for the preparation of Bell states and W-type states, within a shortest preparation time.

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