腔体磁力学中的磁子挤压增强型声子激光技术

IF 4.4 Q1 OPTICS
Qing-Feng Zhang, Yue-Ru Zhou, Fei-Fei Liu, Xue-Yan Wang, Yong-Pan Gao, Ling Fan, Cong Cao
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引用次数: 0

摘要

声子激光器一直是人们感兴趣的课题,具有广阔的应用前景。人们致力于为利用空腔磁力学系统实现声子激光奠定基础,但迄今为止还没有开展相关工作来探索在空腔磁力学中量子挤压设计的声子激光作用。在此,我们以微波谐振器-钇铁石榴石球复合器件为基础,研究了三模空腔磁力学系统中的声子激光作用,重点研究了磁子模式挤压引起的效应。研究发现,磁子挤压可以提高有效的磁子-光子和磁子-声子耦合率。研究表明,可以通过改变挤压强度来设计和增强声子激光作用。该方案为各种应用提供了一种改善有效磁光子和镁光子耦合的新机制,并证明了利用空腔磁力学平台实现高增益和低阈值声子激光器的可行性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Magnon-Squeezing-Enhanced Phonon Lasering in Cavity Magnomechanics

Magnon-Squeezing-Enhanced Phonon Lasering in Cavity Magnomechanics

Phonon lasers have long been a subject of interest and possess broad application prospects. Much effort is devoted to lay the foundation of realizing phonon lasers using cavity magnomechanical systems, but up to now no related work is carried out to explore the quantum-squeezing-engineered phonon laser action in cavity magnomechanics. Here, the phonon laser action is investigated in a three-mode cavity magnomechanical system built based on a microwave resonator-yttrium iron garnet sphere composite device, focusing on the effect induced by the magnon-mode squeezing. It is found that the magnon squeezing can improve the effective magnon–photon and magnon–phonon coupling rates. It is demonstrated that the phonon laser action can be engineered and enhanced by changing the squeezing strength. This scheme provides a new mechanism to improve the effective magnon–photon and magnon–phonon couplings for various applications, and demonstrates the feasibility of realizing high-gain and low-threshold phonon lasers with cavity magnomechanical platforms.

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