Bistability of Cavity Magnon Polaritons

Wang, Yipu; Zhang, Guoqiang; Zhang, Dengke; Li, Tiefu; Hu, C.‐M.; You, J. Q.

doi:10.1103/physrevlett.120.057202

Cited by 371 publications

(307 citation statements)

References 43 publications

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“…In general, the magnetostrictive interaction is of different types depending on the resonance frequencies of the magnon and phonon modes [32], but the dispersive magnon-phonon interaction becomes dominant when the mechanical frequency is much smaller than the magnon frequency [13], which is the case to be considered in the present work. This magnon-phonon coupling is currently small [13], but it can be efficiently enhanced by driving the sphere with a strong microwave field [14,20]. The magnomechanical coupling strength is sensitive to the direction of the bias magnetic field [13], and we adjust the directions of the two bias magnetic fields (see figure 1(a)) such that only in one sphere the magnetostrictive interaction is effectively activated 2 .…”

Section: The Modelmentioning

confidence: 99%

“…This strong coupling offers a possibility to enable coherent information transfer between drastically different information carriers, and thus may find potential applications in quantum information processing, especially when the system becomes hybrid [10], such as by coupling magnons to a superconducting qubit [11,12], to phonons [13,14], or to both microwave and optical photons [15]. Furthermore, various interesting phenomena have been explored in the system of cavity-magnon polaritons, such as the observation of magnon gradient memory [16], the exceptional point [17,18], manipulation of distant spin currents [19], and bistability [20], to name but a few.…”

Section: Introductionmentioning

confidence: 99%

“…The intense magnon drive may bring about unwanted nonlinear effects due to the Kerr nonlinear term  † † m mm m in the Hamiltonian[20,42]. The Kerr coefficient  is inversely proportional to the volume of the sphere.…”

mentioning

confidence: 99%

“…The Kerr coefficient  is inversely proportional to the volume of the sphere. For a 1 mm diam YIG sphere used in[20,42],  p »…”

mentioning

confidence: 99%

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Entangling two magnon modes via magnetostrictive interaction

Zhu

2019

New J. Phys.

163

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We present a scheme to entangle two magnon modes in a cavity magnomechanical system. The two magnon modes are embodied by collective motions of a large number of spins in two macroscopic ferrimagnets, and couple to a single microwave cavity mode via magnetic dipole interaction. We show that by activating the nonlinear magnetostrictive interaction in one ferrimagnet, realized by driving the magnon mode with a strong red-detuned microwave field, the two magnon modes can be prepared in an entangled state. The entanglement is achieved by exploiting the nonlinear magnonphonon coupling and the linear magnon-cavity coupling, and is in the steady state and robust against temperature. The entangled magnon modes in two massive ferrimagnets represent genuinely macroscopic quantum states, and may find applications in the study of macroscopic quantum mechanics and quantum information processing based on magnonics.

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Section: The Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

“…The Kerr coefficient  is inversely proportional to the volume of the sphere. For a 1 mm diam YIG sphere used in[20,42],  p »…”

mentioning

confidence: 99%

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Entangling two magnon modes via magnetostrictive interaction

Zhu

2019

New J. Phys.

163

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“…Although the coupling strength between a single spin and a microwave photon is very weak, stronger coupling can be achieved by the use of collective excitations (also called as magnons) in ferrimagnetic materials such as yttrium iron garnet (YIG, Y 3 Fe 5 O 12 ) [4][5][6][7][8][9]. Various interesting phenomena, including the manipulation of spin current [10,11], the magnon quintuplet state [12], the exceptional point [13] and the bistability of cavity magnon polaritons [14] have been demonstrated in strongly coupled magnonphoton systems. In addition to the fundamental uniform mode, coupling between photons and higher order non-uniform modes has also been studied, with coupling strength depending on the overlap between the magnon and caity modes [15,16].…”

Section: Introductionmentioning

confidence: 99%

Level attraction and level repulsion of magnon coupled with a cavity anti-resonance

Rao

Zhao

et al. 2019

New J. Phys.

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We report on coherent and dissipative coupling between a magnon mode and an anti-resonance of transmission in a cylindrical microwave cavity. By effectively suppressing coherent coupling, we observe the hybridized dispersion to change from level repulsion to level attraction. A careful examination reveals distinct differences in the line shape and phase evolution of transmission spectra between these coupling behaviors. For a quantitative understanding of the interactions between the magnon mode and the cavity anti-resonance, we develop a model which precisely describes our experimental observations, particularly, the signature in the line shape and phase of the microwave transmission. Our work sets a foundation for understanding strong coupling between magnon modes and cavity anti-resonances. In addition, it also confirms the ubiquity of level attraction in coupled magnon-photon systems, which may be helpful to develop future magnon-based hybrid quantum systems.

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Nonreciprocal Transmission and Nonreciprocal Entanglement in a Spinning Microwave Magnomechanical System

et al. 2020

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This study presents nonreciprocal transmission and nonreciprocal magnon–phonon entanglement in a spinning microwave magnomechanical system. This system consists of microwave photons, magnon modes, and phonons. These are created by the vibrational mode of a yttrium iron garnet sphere. This investigation reveals that nonreciprocity is caused by the light that is circulating in a resonator that is experiencing a Fizeau shift. This leads to a difference in the effective detuning frequency of the photon for forwarding and backward drives. A super‐strong transmission isolation rate (>100 dB) and a strong entanglement isolation rate (≈50 dB) are obtained by applying the experimental parameters. This scheme opens a new route for exploiting a variety of nonreciprocal effects, and it provides the theoretical basis for the design and realization of magnetically controllable isolators and diodes.

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Bistability of Cavity Magnon Polaritons

Cited by 371 publications

References 43 publications

Entangling two magnon modes via magnetostrictive interaction

Entangling two magnon modes via magnetostrictive interaction

Level attraction and level repulsion of magnon coupled with a cavity anti-resonance

Nonreciprocal Transmission and Nonreciprocal Entanglement in a Spinning Microwave Magnomechanical System

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