Continuous time crystal coupled to a mechanical mode as a cavity-optomechanics-like platform

J. T. Mäkinen; Petri Heikkinen; S. Autti; V. V. Zavjalov; Vladimir Eltsov

doi:10.1038/s41467-025-64673-8

Continuous time crystal coupled to a mechanical mode as a cavity-optomechanics-like platform

J. T. Mäkinen
, Petri Heikkinen
, S. Autti
, V. V. Zavjalov
, Vladimir Eltsov

Research output: Contribution to journal › Article › peer-review

Abstract

Time crystals are an enigmatic phase of matter in which a quantum mechanical system displays repetitive, observable motion – they spontaneously break the time translation symmetry. On the other hand optomechanical systems, where mechanical and optical degrees of freedom are coupled, are well established and enable a range of applications and measurements with unparalleled precision. Here, we connect a time crystal formed of magnetic quasiparticles, magnons, to a mechanical resonator, a gravity wave mode on a nearby liquid surface, and show that their joint dynamics evolves as a cavity optomechanical system. Our results pave way for exploiting the spontaneous coherence of time crystals in an optomechanical setting and remove the experimental barrier between time crystals and other phases of condensed matter.

Original language	English
Article number	9050
Journal	Nature Communications
Volume	16
DOIs	https://doi.org/10.1038/s41467-025-64673-8
Publication status	Published - 16 Oct 2025

Keywords

Bose-Einstein condensates
Fluid dynamics
Quantum physics

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10.1038/s41467-025-64673-8Licence: CC BY-NC-ND

Cite this

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abstract = "Time crystals are an enigmatic phase of matter in which a quantum mechanical system displays repetitive, observable motion – they spontaneously break the time translation symmetry. On the other hand optomechanical systems, where mechanical and optical degrees of freedom are coupled, are well established and enable a range of applications and measurements with unparalleled precision. Here, we connect a time crystal formed of magnetic quasiparticles, magnons, to a mechanical resonator, a gravity wave mode on a nearby liquid surface, and show that their joint dynamics evolves as a cavity optomechanical system. Our results pave way for exploiting the spontaneous coherence of time crystals in an optomechanical setting and remove the experimental barrier between time crystals and other phases of condensed matter.",

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AU - Mäkinen, J. T.

AU - Heikkinen, Petri

AU - Autti, S.

AU - Zavjalov, V. V.

AU - Eltsov, Vladimir

PY - 2025/10/16

Y1 - 2025/10/16

N2 - Time crystals are an enigmatic phase of matter in which a quantum mechanical system displays repetitive, observable motion – they spontaneously break the time translation symmetry. On the other hand optomechanical systems, where mechanical and optical degrees of freedom are coupled, are well established and enable a range of applications and measurements with unparalleled precision. Here, we connect a time crystal formed of magnetic quasiparticles, magnons, to a mechanical resonator, a gravity wave mode on a nearby liquid surface, and show that their joint dynamics evolves as a cavity optomechanical system. Our results pave way for exploiting the spontaneous coherence of time crystals in an optomechanical setting and remove the experimental barrier between time crystals and other phases of condensed matter.

AB - Time crystals are an enigmatic phase of matter in which a quantum mechanical system displays repetitive, observable motion – they spontaneously break the time translation symmetry. On the other hand optomechanical systems, where mechanical and optical degrees of freedom are coupled, are well established and enable a range of applications and measurements with unparalleled precision. Here, we connect a time crystal formed of magnetic quasiparticles, magnons, to a mechanical resonator, a gravity wave mode on a nearby liquid surface, and show that their joint dynamics evolves as a cavity optomechanical system. Our results pave way for exploiting the spontaneous coherence of time crystals in an optomechanical setting and remove the experimental barrier between time crystals and other phases of condensed matter.

KW - Bose-Einstein condensates

KW - Fluid dynamics

KW - Quantum physics

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Continuous time crystal coupled to a mechanical mode as a cavity-optomechanics-like platform

Abstract

Keywords

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Seminar: Probing the free surface of topological superfluid helium-3 with magnon Bose-Einstein condensate

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Continuous time crystal coupled to a mechanical mode as a cavity-optomechanics-like platform

Abstract

Keywords

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Activities

Seminar: Probing the free surface of topological superfluid helium-3 with magnon Bose-Einstein condensate

Cite this