Unveiling the double-peak structure of quantum oscillations in the specific heat

Zhuo Yang; Benoît Fauqué; Toshihiro Nomura; Takashi Shitaokoshi; Sunghoon Kim; Debanjan Chowdhury; Zuzana Pribulová; Jozef Kačmarčík; Alexandre Pourret; Georg Knebel; Dai Aoki; Thierry Klein; Duncan K. Maude; Christophe Marcenat; Yoshimitsu Kohama

doi:10.1038/s41467-023-42730-4

Unveiling the double-peak structure of quantum oscillations in the specific heat

Zhuo Yang
, Benoît Fauqué
, Toshihiro Nomura
, Takashi Shitaokoshi
, Sunghoon Kim
, Debanjan Chowdhury
, Zuzana Pribulová
, Jozef Kačmarčík
, Alexandre Pourret
, Georg Knebel
, Dai Aoki
, Thierry Klein
, Duncan K. Maude
, Christophe Marcenat
, Yoshimitsu Kohama

University of Tokyo
Collège de France
Cornell University
Institute of Experimental Physics Slovak Academy of Sciences
CEA-INAC-PHELIQS
Tohoku University
LTHE (UMR 5564 CNRS/IRD/Université de Grenoble)
INSA

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Quantum oscillation phenomenon is an essential tool to understand the electronic structure of quantum matter. Here we report a systematic study of quantum oscillations in the electronic specific heat C _el in natural graphite. We show that the crossing of a single spin Landau level and the Fermi energy give rise to a double-peak structure, in striking contrast to the single peak expected from Lifshitz-Kosevich theory. Intriguingly, the double-peak structure is predicted by the kernel term for C _el/T in the free electron theory. The C _el/T represents a spectroscopic tuning fork of width 4.8k_B T which can be tuned at will to resonance. Using a coincidence method, the double-peak structure can be used to accurately determine the Landé g-factors of quantum materials. More generally, the tuning fork can be used to reveal any peak in fermionic density of states tuned by magnetic field, such as Lifshitz transition in heavy-fermion compounds.

langue originale	Anglais
Numéro d'article	7006
journal	Nature Communications
Volume	14
Numéro de publication	1
Les DOIs	https://doi.org/10.1038/s41467-023-42730-4
état	Publié - 1 déc. 2023
Modification externe	Oui

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Yang, Z., Fauqué, B., Nomura, T., Shitaokoshi, T., Kim, S., Chowdhury, D., Pribulová, Z., Kačmarčík, J., Pourret, A., Knebel, G., Aoki, D., Klein, T., Maude, D. K., Marcenat, C., & Kohama, Y. (2023). Unveiling the double-peak structure of quantum oscillations in the specific heat. Nature Communications, 14(1), Article 7006. https://doi.org/10.1038/s41467-023-42730-4

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title = "Unveiling the double-peak structure of quantum oscillations in the specific heat",

abstract = "Quantum oscillation phenomenon is an essential tool to understand the electronic structure of quantum matter. Here we report a systematic study of quantum oscillations in the electronic specific heat C el in natural graphite. We show that the crossing of a single spin Landau level and the Fermi energy give rise to a double-peak structure, in striking contrast to the single peak expected from Lifshitz-Kosevich theory. Intriguingly, the double-peak structure is predicted by the kernel term for C el/T in the free electron theory. The C el/T represents a spectroscopic tuning fork of width 4.8kB T which can be tuned at will to resonance. Using a coincidence method, the double-peak structure can be used to accurately determine the Land{\'e} g-factors of quantum materials. More generally, the tuning fork can be used to reveal any peak in fermionic density of states tuned by magnetic field, such as Lifshitz transition in heavy-fermion compounds.",

author = "Zhuo Yang and Beno{\^i}t Fauqu{\'e} and Toshihiro Nomura and Takashi Shitaokoshi and Sunghoon Kim and Debanjan Chowdhury and Zuzana Pribulov{\'a} and Jozef Ka{\v c}mar{\v c}{\'i}k and Alexandre Pourret and Georg Knebel and Dai Aoki and Thierry Klein and Maude, \{Duncan K.\} and Christophe Marcenat and Yoshimitsu Kohama",

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doi = "10.1038/s41467-023-42730-4",

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AU - Yang, Zhuo

AU - Fauqué, Benoît

AU - Nomura, Toshihiro

AU - Shitaokoshi, Takashi

AU - Kim, Sunghoon

AU - Chowdhury, Debanjan

AU - Pribulová, Zuzana

AU - Kačmarčík, Jozef

AU - Pourret, Alexandre

AU - Knebel, Georg

AU - Aoki, Dai

AU - Klein, Thierry

AU - Maude, Duncan K.

AU - Marcenat, Christophe

AU - Kohama, Yoshimitsu

PY - 2023/12/1

Y1 - 2023/12/1

N2 - Quantum oscillation phenomenon is an essential tool to understand the electronic structure of quantum matter. Here we report a systematic study of quantum oscillations in the electronic specific heat C el in natural graphite. We show that the crossing of a single spin Landau level and the Fermi energy give rise to a double-peak structure, in striking contrast to the single peak expected from Lifshitz-Kosevich theory. Intriguingly, the double-peak structure is predicted by the kernel term for C el/T in the free electron theory. The C el/T represents a spectroscopic tuning fork of width 4.8kB T which can be tuned at will to resonance. Using a coincidence method, the double-peak structure can be used to accurately determine the Landé g-factors of quantum materials. More generally, the tuning fork can be used to reveal any peak in fermionic density of states tuned by magnetic field, such as Lifshitz transition in heavy-fermion compounds.

AB - Quantum oscillation phenomenon is an essential tool to understand the electronic structure of quantum matter. Here we report a systematic study of quantum oscillations in the electronic specific heat C el in natural graphite. We show that the crossing of a single spin Landau level and the Fermi energy give rise to a double-peak structure, in striking contrast to the single peak expected from Lifshitz-Kosevich theory. Intriguingly, the double-peak structure is predicted by the kernel term for C el/T in the free electron theory. The C el/T represents a spectroscopic tuning fork of width 4.8kB T which can be tuned at will to resonance. Using a coincidence method, the double-peak structure can be used to accurately determine the Landé g-factors of quantum materials. More generally, the tuning fork can be used to reveal any peak in fermionic density of states tuned by magnetic field, such as Lifshitz transition in heavy-fermion compounds.

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Unveiling the double-peak structure of quantum oscillations in the specific heat

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