Quantum oscillation signatures of the Bloch-Grüneisen temperature in the Dirac semimetal ZrTe5

Research output: Contribution to journalResearch articleContributedpeer-review

Contributors

  • S. Galeski - , University of Bonn, Helmholtz-Zentrum Dresden-Rossendorf (Author)
  • K. Araki - , National Defense Academy of Japan (Author)
  • O. K. Forslund - , University of Zurich, Uppsala University (Author)
  • R. Wawrzyńczak - , Max Planck Institute for Chemical Physics of Solids (Author)
  • H. F. Legg - , University of Basel (Author)
  • P. K. Sivakumar - , Max Planck Institute of Microstructure Physics (Author)
  • U. Miniotaite - , KTH Royal Institute of Technology (Author)
  • F. Elson - , KTH Royal Institute of Technology (Author)
  • M. Månsson - , KTH Royal Institute of Technology (Author)
  • C. Witteveen - , University of Geneva (Author)
  • F. O. Von Rohr - , University of Geneva (Author)
  • A. Q.R. Baron - , Japan Synchrotron Radiation Research Institute (Author)
  • D. Ishikawa - , Japan Synchrotron Radiation Research Institute (Author)
  • Q. Li - , Brookhaven National Laboratory (Author)
  • G. Gu - , Brookhaven National Laboratory (Author)
  • L. X. Zhao - , CAS - Institute of Physics, Songshan Lake Materials Laboratory, University of Chinese Academy of Sciences (Author)
  • W. L. Zhu - , CAS - Institute of Physics, University of Chinese Academy of Sciences, Shaanxi Normal University (Author)
  • G. F. Chen - , CAS - Institute of Physics, Songshan Lake Materials Laboratory, University of Chinese Academy of Sciences (Author)
  • Y. Wang - , CAS - Institute of Physics (Author)
  • S. S.P. Parkin - , Max Planck Institute of Microstructure Physics (Author)
  • D. Grobunov - , Helmholtz-Zentrum Dresden-Rossendorf (Author)
  • S. Zherlitsyn - , Helmholtz-Zentrum Dresden-Rossendorf (Author)
  • B. Vlaar - , Vienna University of Technology (Author)
  • D. H. Nguyen - , Vienna University of Technology (Author)
  • S. Paschen - , Vienna University of Technology (Author)
  • P. Narang - , University of California at Los Angeles (Author)
  • C. Felser - , University of Basel (Author)
  • J. Wosnitza - , Clusters of Excellence ct.qmat: Complexity and Topology in Quantum Matter, Chair of Physics of High Magnetic Fields (Author)
  • T. Meng - , Clusters of Excellence ct.qmat: Complexity and Topology in Quantum Matter, Chair of Theoretical Solid State Physics (Author)
  • Y. Sassa - , Chalmers University of Technology (Author)
  • S. A. Hartnoll - , University of Cambridge (Author)
  • J. Gooth - , University of Bonn, Max Planck Institute for Chemical Physics of Solids (Author)

Abstract

The electron-phonon interaction is in many ways a solid state equivalent of quantum electrodynamics. Being always present, the e-p coupling is responsible for the intrinsic resistance of metals at finite temperatures, making it one of the most fundamental interactions present in solids. In typical metals, different regimes of e-p scattering are separated by a characteristic phonon energy scale - the Debye temperature. However, in metals harboring very small Fermi surfaces a new scale emerges - the Bloch-Grüneisen temperature. This is a temperature at which the average phonon momentum becomes comparable to the Fermi momentum of the electrons. Here we report sub-Kelvin transport and sound propagation experiments on the Dirac semimetal ZrTe5. The combination of the simple band structure with only a single small Fermi surface sheet allowed us to directly observe the Bloch-Grüneisen temperature and its consequences on electronic transport of a 3D metal in the limit where the small size of the Fermi surface leads to effective restoration of translational invariance of free space. Our results indicate that on entering this hydrodynamic transport regime, the viscosity of the Dirac electronic liquid undergoes an anomalous increase beyond the theoretically predicted T5 temperature dependence. Extension of our measurements to strong magnetic fields reveal that, despite the dimensional reduction of the electronic band structure, the electronic liquid retains characteristics of the zero-field hydrodynamic regime up to the quantum limit. This is vividly reflected by an anomalous suppression of the amplitude of quantum oscillations seen in the Shubnikov-de Haas effect.

Details

Original languageEnglish
Article numberL121103
JournalPhysical Review B
Volume110
Issue number12
Publication statusPublished - 15 Sept 2024
Peer-reviewedYes