Quantum speed limit of a single atom in a squeezed optical cavity mode

Ma, Ya-Jie; Gao, Xue-Chen; Wu, Shunan; Yu, Chang-shui

doi:10.1088/1674-1056/acbd2b

Chinese Phys. B

2023

DOI: 10.1088/1674-1056/acbd2b

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Quantum speed limit of a single atom in a squeezed optical cavity mode

Ya-Jie Ma

Xue-Chen Gao

Shunan Wu

et al.

Abstract: We theoretically study the quantum speed limit of a single atom trapped in a Fabry-Perot microresonator. The cavity mode will be squeezed when a driving laser is applied to the second-order nonlinear medium, and the effective Hamiltonian can be obtained under the Bogoliubov squeezing transformation. The analytical expression of evolved atom state can be obtained by using the non-Hermitian Schrödinger equation for the initial excited state, and the quantum speed limit time coincides very well for both the analy… Show more

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Cited by 2 publications

References 80 publications

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Quantum squeezing-induced quantum entanglement and EPR steering in a coupled optomechanical system

Wu,

Bai,

et al. 2023

Opt. Express

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We propose a theoretical project in which quantum squeezing induces quantum entanglement and Einstein-Podolsky-Rosen steering in a coupled whispering-gallery-mode optomechanical system. Through pumping the χ(2)-nonlinear resonator with the phase matching condition, the generated squeezed resonator mode and the mechanical mode of the optomechanical resonator can generate strong quantum entanglement and EPR steering, where the squeezing of the nonlinear resonator plays the vital role. The transitions from zero entanglement to strong entanglement and one-way steering to two-way steering can be realized by adjusting the system parameters appropriately. The photon-photon entanglement and steering between the two resonators can also be obtained by deducing the amplitude of the driving laser. Our project does not need an extraordinarily squeezed field, and it is convenient to manipulate and provides a novel and flexible avenue for diverse applications in quantum technology dependent on both optomechanical and photon-photon entanglement and steering.

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Quantum squeezing-induced quantum entanglement and EPR steering in a coupled optomechanical system

Wu,

Bai,

et al. 2023

Opt. Express

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Quantum evolution speed induced by Hamiltonian

Dong,

Qin,

Liu

et al. 2023

Acta Phys. Sin.

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In the issue of quantum evolution, quantum evolution speed is usually quantified by the time rate of change of state distance between the initial sate and its time evolution. In this paper, the path distance of quantum evolution is introduced to study the evolution of a quantum system, through the approach combined with basic theory of quantum evolution and the linear algebra. In a quantum unitary system, the quantum evolution operator contains the path information of the quantum evolution, where the path distance is determined by the principal argument of the eigenvalues of the unitary operator. Accordingly, the instantaneous quantum evolution speed is proportional to the distance between the maximum and minimum eigenvalues of the Hamiltonian. As one of the applications, the path distance and the instantaneous quantum evolution speed could be used to form a new lower bound of the real evolution time, which depends on the evolution operator and Hamiltonian, and is independent of the initial state. It is found that the lower bound presented here is exactly equal to the real evolution time in the range $[0,\frac{\pi}{2\omega_H}]$. The tool of path distance and instantaneous quantum evolution speed introduced here provides new method for the related researches

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Quantum speed limit of a single atom in a squeezed optical cavity mode

Cited by 2 publications

References 80 publications

Quantum squeezing-induced quantum entanglement and EPR steering in a coupled optomechanical system

Quantum squeezing-induced quantum entanglement and EPR steering in a coupled optomechanical system

Quantum evolution speed induced by Hamiltonian

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