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Main Authors: Gu, Ge-Ge, Li, Dong-Sheng, Chen, Ye-Hong, Huang, Bi-Hua, Xia, Yan
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2408.00471
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_version_ 1866909536938360832
author Gu, Ge-Ge
Li, Dong-Sheng
Chen, Ye-Hong
Huang, Bi-Hua
Xia, Yan
author_facet Gu, Ge-Ge
Li, Dong-Sheng
Chen, Ye-Hong
Huang, Bi-Hua
Xia, Yan
contents We propose a protocol for the preparation of high-fidelity entangled cat states with composite pulses. The physical model contains two Kerr-nonlinear resonators and a cavity. By properly designing the parameters, each Kerr-nonlinear resonator is confined in the cat-state subspace and the entangled cat states can be generated efficiently. We introduce composite two-photon drives with multiple amplitudes and frequencies to improve the fidelity of the entangled cat states in the presence of parameter errors. The performance of the protocol is estimated by taking into account the parametric errors and decoherence. Numerical simulation results show that the protocol is insensitive to timing error and detuning error, and has strong robustness to decoherence. We hope the protocol may provide a method for preparing stable entangled cat states.
format Preprint
id arxiv_https___arxiv_org_abs_2408_00471
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Preparation of high fidelity entangled cat states with composite pulses
Gu, Ge-Ge
Li, Dong-Sheng
Chen, Ye-Hong
Huang, Bi-Hua
Xia, Yan
Quantum Physics
We propose a protocol for the preparation of high-fidelity entangled cat states with composite pulses. The physical model contains two Kerr-nonlinear resonators and a cavity. By properly designing the parameters, each Kerr-nonlinear resonator is confined in the cat-state subspace and the entangled cat states can be generated efficiently. We introduce composite two-photon drives with multiple amplitudes and frequencies to improve the fidelity of the entangled cat states in the presence of parameter errors. The performance of the protocol is estimated by taking into account the parametric errors and decoherence. Numerical simulation results show that the protocol is insensitive to timing error and detuning error, and has strong robustness to decoherence. We hope the protocol may provide a method for preparing stable entangled cat states.
title Preparation of high fidelity entangled cat states with composite pulses
topic Quantum Physics
url https://arxiv.org/abs/2408.00471