Higher-order exceptional point in a blue-detuned non-Hermitian cavity optomechanical system

• URL: http://arxiv.org/abs/2205.07184v4
• Date: Wed, 28 Sep 2022 00:48:03 GMT
• Title: Higher-order exceptional point in a blue-detuned non-Hermitian cavity optomechanical system
• Authors: Wei Xiong, Zhuanxia Li, Guo-Qiang Zhang, Mingfeng Wang, Hai-Chao Li, Xiao-Qing Luo, Jianjiao Chen
• Abstract summary: We propose a non-Hermitian three-mode optomechanical system in the blue-sideband regime for predicting the third-order EP (EP3) For the gain (loss) MR, we find only two degenerate EP3s or EP2s can be predicted by tuning enhanced coupling strength. Our proposal provides a potential way to predict higher-order EPs or multiple EP2s and study multimode quantum squeezing around EPs.
• Score: 5.001077638364239
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Higher-order exceptional points (EPs) in non-Hermitian systems have attracted great interest due to their advantages in sensitive enhancement and distinct topological features. However, realization of such EPs is still challenged because more fine-tuning parameters is generically required in quantum systems, compared to the second-order EP (EP2). Here, we propose a non-Hermitian three-mode optomechanical system in the blue-sideband regime for predicting the third-order EP (EP3). By deriving the pseudo-Hermitian condition for the proposed system, one cavity with loss and the other one with gain must be required. Then we show EP3 or EP2 can be observed when the mechanical resonator (MR) is neutral, loss or gain. For the neutral MR, we find both two degenerate or two non-degenerate EP3s can be predicted by tuning system parameters in the parameter space, while four non-degenerate EP2s can be observed when the system parameters derivate from EP3s, which is distinguished from the previous study in the red-detuned optomechanical system. For the gain (loss) MR, we find only two degenerate EP3s or EP2s can be predicted by tuning enhanced coupling strength. Our proposal provides a potential way to predict higher-order EPs or multiple EP2s and study multimode quantum squeezing around EPs using the blue-detuned non-Hermitian optomechanical systems.

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