Ultrasonic Dispersion in All Elastic Moduli and Softening at Low Temperatures in Filled Skutterudite LaFe4Sb12

To clarify the origin of ultrasonic dispersion due to the so-called rattling motion in LaFe4Sb12, we measured the temperature dependences of elastic moduli and ultrasonic attenuation. We found the ultrasonic dispersion to be between 35 and 80 K in all elastic moduli, suggesting no-mode-selectivity o...

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Bibliographic Details
Published in:Journal of the Physical Society of Japan 2009-08, Vol.78 (8)
Main Authors: ISHII, Isao, FUJITA, Takahiro, MORI, Ikuko, SUGAWARA, Hitoshi, YOSHIZAWA, Masahito, TAKEGAHARA, Katsuhiko, SUZUKI, Takashi
Format: Article
Language:English
Subjects:
Acoustical properties of solids
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Condensed matter: structure, mechanical and thermal properties
Elasticity, elastic constants
Electron states
Exact sciences and technology
Mechanical and acoustical properties of condensed matter
Mechanical properties of solids
Methods of electronic structure calculations
Physics
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Summary:To clarify the origin of ultrasonic dispersion due to the so-called rattling motion in LaFe4Sb12, we measured the temperature dependences of elastic moduli and ultrasonic attenuation. We found the ultrasonic dispersion to be between 35 and 80 K in all elastic moduli, suggesting no-mode-selectivity of ultrasound. Experimental results and theoretically calculated density of states indicate that the d-electronic states of transition metal ions play an important role in ultrasonic dispersion. The theory based on the coupling between an acoustic phonon and some optical phonons interacting with electrons is compatible with no-mode-selective ultrasonic dispersion, and it suggests a stronger electron-phonon coupling in all elastic modes in LaFe4Sb12. Low-temperature elastic softening was observed in all elastic moduli, and it continues down to 0.4 K. There is a possibility that low-temperature softening originates from quantum tunneling motion or a novel quantum effect of rattling motion.
ISSN:0031-9015
1347-4073
DOI:10.1143/jpsj.78.084601