Observability of cyclotron resonance in the hydrodynamic regime of bilayer graphene

Joseph R. Cruise; Alexander Seidel; Erik A. Henriksen; Giovanni Vignale

doi:10.1103/PhysRevB.110.115416

Observability of cyclotron resonance in the hydrodynamic regime of bilayer graphene

Joseph R. Cruise
, Alexander Seidel
, Erik A. Henriksen
, Giovanni Vignale

Department of Physics

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

3 Scopus citations

Abstract

We offer theoretical predictions for the values of the resonant frequencies of transport for the hydrodynamic description of bilayer graphene, as well as provide quantification for the relative strength of this signal throughout phase space. Our calculations are based on classical fluid dynamics equations derived from the Boltzmann equation for bilayer graphene, and suggest that while this resonance is accessible to current experimental techniques, the same mechanism which causes the hydrodynamic resonance to differ from the Fermi-liquid value is responsible for a significant broadening of the peak.

Original language	English
Article number	115416
Journal	Physical Review B
Volume	110
Issue number	11
DOIs	https://doi.org/10.1103/PhysRevB.110.115416
State	Published - Sep 15 2024

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title = "Observability of cyclotron resonance in the hydrodynamic regime of bilayer graphene",

abstract = "We offer theoretical predictions for the values of the resonant frequencies of transport for the hydrodynamic description of bilayer graphene, as well as provide quantification for the relative strength of this signal throughout phase space. Our calculations are based on classical fluid dynamics equations derived from the Boltzmann equation for bilayer graphene, and suggest that while this resonance is accessible to current experimental techniques, the same mechanism which causes the hydrodynamic resonance to differ from the Fermi-liquid value is responsible for a significant broadening of the peak.",

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AU - Seidel, Alexander

AU - Henriksen, Erik A.

AU - Vignale, Giovanni

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AB - We offer theoretical predictions for the values of the resonant frequencies of transport for the hydrodynamic description of bilayer graphene, as well as provide quantification for the relative strength of this signal throughout phase space. Our calculations are based on classical fluid dynamics equations derived from the Boltzmann equation for bilayer graphene, and suggest that while this resonance is accessible to current experimental techniques, the same mechanism which causes the hydrodynamic resonance to differ from the Fermi-liquid value is responsible for a significant broadening of the peak.

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DO - 10.1103/PhysRevB.110.115416

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Observability of cyclotron resonance in the hydrodynamic regime of bilayer graphene

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