The Yamaji Oscillations of the Ultrasonic Attenuation in the Quasi Two Dimensional Systems with the Periodically Undulating Fermi Surfaces : Condensed Matter: Structure, etc.
スポンサーリンク
概要
- 論文の詳細を見る
The ultrasonic attenuation is investigated for such quasi two dimensional systems with periodically undulating cylindrical Fermi surfaces as organic metals and superlattices. We obtained the most general forms of the ac-nonlocal magnetoconductivity, which becomes the dc-local magnetoconductivity obtained earlier in the limit of the high magnetic strength, where both the frequency and wave number can be assumed to become zero. The directional dependence of the magnetic field on the ultrasonic attenuation, one of what we call the Yamaji oscillations, appears in the high-field limits, only for longitudinal waves propagating parallel to t,he c-axis and for transverse waves polarized along the c-axis in the case of propagation in the plane perpendicular to the c-axis.
- 社団法人日本物理学会の論文
- 2000-11-15
著者
-
INOUE Seiichirou
Department of Applied Science, Faculty of Engineering College of General Education, Kyushu Universit
-
Itou Yoshihide
Department Of Physics Kyushu University
-
NARITA Kouichirou
Department of Physics, Kyushu University
-
Inoue Seiichirou
Department Of Applied Science Faculty Of Engineering College Of General Education Kyushu University
-
Inoue Seiichirou
Department Of Physics Kyushu University
-
Narita Kouichirou
Department Of Physics Kyushu University:(present)ibm Japan Ltd.
関連論文
- Line Shapes in Cyclotron Resonance in Metals with Non-Ellipsoidal Fermi Surfaces
- Anisotropy of the Amplitude of the Giant Quantum Oscillations in the Magnetoacoustic Attenuation in Bismuth
- The Yamaji Oscillations of the Ultrasonic Attenuation in the Quasi Two Dimensional Systems with the Periodically Undulating Fermi Surfaces : Condensed Matter: Structure, etc.
- Anisotropy of the Ultrasonic Attenuation in Metals
- Ultrasonic Amplification in Semimetals in Crossed Electric and Magnetic Fields
- Current Saturation in GaAs Induced by Sound Amplification