Experimental implementations of cavity-magnon systems: from ultra strong coupling to applications in precision measurement

Flower, Graeme; Goryachev, Maxim; Bourhill, Jeremy; Tobar, Michael E.

doi:10.1088/1367-2630/ab3e1c

Cited by 80 publications

(60 citation statements)

References 76 publications

(115 reference statements)

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“…The achieved peak coupling strength is a high value as compared to other photon-to-magnon hybrids, exceeding the coupling strength in typical cavity-based (9,13,16), split ring-based (43), and on-chip resonator-based (19,20) hybrids. This coupling strength is comparable only with the coupling in macroscopic photon-to-magnon hybrids (14,15,17,18,35), where dimensions of the ferromagnetic oscillator reach several millimeters. Along with the total coupling, the system demonstrates a strong single-spin coupling strength (9,13,14,35,43) (19,20).…”

Section: Resultsmentioning

confidence: 93%

Ultrastrong photon-to-magnon coupling in multilayered heterostructures involving superconducting coherence via ferromagnetic layers

et al. 2021

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The critical step for future quantum industry demands realization of efficient information exchange between different-platform hybrid systems that can harvest advantages of distinct platforms. The major restraining factor for the progress in certain hybrids is weak coupling strength between the elemental particles. In particular, this restriction impedes a promising field of hybrid magnonics. In this work, we propose an approach for realization of on-chip hybrid magnonic systems with unprecedentedly strong coupling parameters. The approach is based on multilayered microstructures containing superconducting, insulating, and ferromagnetic layers with modified photon phase velocities and magnon eigenfrequencies. The enhanced coupling strength is provided by the radically reduced photon mode volume. Study of the microscopic mechanism of the photon-to-magnon coupling evidences formation of the long-range superconducting coherence via thick strong ferromagnetic layers in superconductor/ferromagnet/superconductor trilayer in the presence of magnetization precession. This discovery offers new opportunities in microwave superconducting spintronics for quantum technologies.

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Section: Resultsmentioning

confidence: 93%

Ultrastrong photon-to-magnon coupling in multilayered heterostructures involving superconducting coherence via ferromagnetic layers

et al. 2021

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“…This is the case of the ultrastrong coupling regime which is when g/! > 0.1 and it is also where approaches such as the rotating wave approximation begin to breakdown here [51]. Therefore, we will briefly investigate how our approach can be applied to one of these systems: a double-post, re-entrant microwave resonator coupled to a YIG sphere as investi- gated by Goryachev and co-workers [5]).…”

Section: Applicability To the Ultrastrong Coupling Regimementioning

confidence: 99%

Electromagnetic Approach to Cavity Spintronics

et al. 2021

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The fields of cavity quantum electrodynamics and magnetism have recently merged into 'cavity spintronics', investigating a quasiparticle that emerges from the strong coupling between standing electromagnetic waves confined in a microwave cavity resonator and the quanta of spin waves, magnons. This phenomenon is now expected to be employed in a variety of devices for applications ranging from quantum communication to dark matter detection. To be successful, most of these applications require a vast control of the coupling strength, resulting in intensive e↵orts to understanding coupling by a variety of di↵erent approaches. Here, the electromagnetic properties of both resonator and magnetic samples are investigated to provide a comprehensive understanding of the coupling between these two systems. Because the coupling is a consequence of the excitation vector fields, which directly interact with magnetisation dynamics, a highly-accurate electromagnetic perturbation theory is employed which predicts the resonant hybrid mode frequencies for any field configuration within the cavity resonator. The coupling is shown to be strongly dependent not only on the excitation vector fields and sample's magnetic properties but also on the sample's shape. These findings are illustrated by applying the theoretical framework to two distinct experiments: a magnetic sphere placed in a three-dimensional resonator, and a rectangular, magnetic prism placed on a two-dimensional resonator. The theory provides comprehensive understanding of the overall behaviour of strongly coupled systems and it can be easily modified for a variety of other systems.

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“…Any product of two even (odd) matrices is even and a product of even (odd) and odd (even) matrices becomes odd. To take the non-relativistic limit of the Hamiltonian, we have to diagonalize the Hamiltonian (26) and expand the upper block diagonal part in powers of 1/m. More precisely, 1/m expansion is recognized as an expansion with respect to two parameters, (mx) −1 and v/c.…”

Section: Non-relativistic Limit Of Dirac Equationmentioning

confidence: 99%

“…Let us show the ability of magnon gravitational detectors by giving constraints on high frequency gravitational waves. Recently, measurements of resonance fluorescence of magnons induced by the axion dark matter was conducted and upper bounds on an axion-electron coupling constant have been obtained [25,26]. Such an axion-magnon resonance [33] has a similar mechanism to our gravitonmagnon resonance.…”

Section: Magnon Gravitational Wave Detectorsmentioning

confidence: 99%

“…As a result, we obtain a formalism for non-relativistic fermions in curved spacetime, including a gravitational wave background as a special case. Finally, as a demonstration, we will give upper limits on the spectral density of continuous gravitational waves (95% CL): 7.5 × 10 −19 [Hz −1/2 ] at 14 GHz and 8.7 × 10 −18 [Hz −1/2 ] at 8.2 GHz, respectively, by utilizing results of magnon experiments conducted recently [25,26].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A formalism for magnon gravitational wave detectors

Ito

Soda

2020

Eur. Phys. J. C

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In order to detect high frequency gravitational waves, we need a new detection method. In this paper, we develop a formalism for a gravitational wave detector using magnons in a cavity. Using Fermi normal coordinates and taking the non-relativistic limit, we obtain a Hamiltonian for magnons in gravitational wave backgrounds. Given the Hamiltonian, we show how to use the magnons for detecting high frequency gravitational waves. Furthermore, as a demonstration of the magnon gravitational wave detector, we give upper limits on GHz gravitational waves by utilizing known results of magnon experiments for an axion dark matter search.

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Experimental implementations of cavity-magnon systems: from ultra strong coupling to applications in precision measurement

Cited by 80 publications

References 76 publications

Ultrastrong photon-to-magnon coupling in multilayered heterostructures involving superconducting coherence via ferromagnetic layers

Ultrastrong photon-to-magnon coupling in multilayered heterostructures involving superconducting coherence via ferromagnetic layers

Electromagnetic Approach to Cavity Spintronics

A formalism for magnon gravitational wave detectors

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