SPring-8, the large synchrotron radiation facility

The researchers at Japan Synchrotron Radiation Research Institute (JASRI), RIKEN, Advanced Institute for Materials Research (WPI-AIMR, Tohoku University), and Shimane University, in collaboration with the University of Tokyo, have conducted a study on cage compounds -a group of compounds viewed as promising candidates for use in elements utilized to generate electric energy -and succeeded in visualizing the atomic motions that play a functional role. Electric-energy generation leveraging waste heat is gaining expectations as a promising technology for sustainable energy technology, and cage compounds are considered capable of providing elemental material.

A temperature difference across a stub of material gives rise to a small end-to-end potential difference. This phenomena, called the “thermoelectric effect,”^(*1) can be applied to power generation using waste heat, thus gathering high expectations for use in sustainable energy technologies. One of the key properties for a “thermoelectric material”^(*2) -i.e. one that exhibits the thermoelectric effect -to gain high conversion efficiency is to maintain a temperature at one end of the material that is different from the temperature at the other end. In other words, the material should be a poor heat conductor but a good electric conductor. As a good electric conductor generally tends to exhibit good thermal conduction, upgrading power-generation property is no easy task.

Compounds classed as “clathrates”^(*3) have a cage-like network structure with a foreign atom trapped within it, which makes “rattling”^(*4) motions in the confined space. The rattling motion has the effect of suppressing lattice vibration (i.e. reduced thermal conduction) while it contributes to increased electric conduction. These two properties make this class of compounds a highly-promising candidate for good thermoelectric materials. However, a detailed understanding of how the rattling motion hinders thermal conduction has been out of reach. A clear understanding of the role played by the rattling motion has been strongly desired, because it is expected to pave the way to the development of high-performance thermoelectric materials, enabling utilization of the knowledge of atomic motions in design.

The research group conducted high-precision structural analysis on three types of clathrate compounds, each with significantly distinct properties in terms of thermal conduction, using the synchrotron radiation X-ray available at SPring-8.^(*5) Potential distribution within the crystal was closely examined based on the structural information. The results clearly indicated, for the first time in the world, that thermal conductivity decreases uniformly as the extent of the impact exerted by intra-cage rattling increases.

The success of this approach indicates the possibility of forecasting thermal conductivity characteristics if only a tiny single crystal of a candidate material, a size roughly of 0.01mm, is available. The approach is expected to provide a direct evaluation method conducive to informed design and development of atomic-motion-leveraged thermoelectric materials that are to be used in electricity-generating elements for the utilization of waste heat.

The research reported here was conducted by the research group led by Mr. Akihiko Fujiwara (Chief researcher, JSARI), Mr. Masaki Takada (senior researcher, RIKEN), Prof. Katsumi Tanigaki (WPI-AIMR, Tohoku University), and Prof. Hiroshi Tanaka (Shimane University), and the results were published on the online publication of “Physical Review B” (a journal of American Physical Society) on April 17, 2012.

Publication:
"Quantitative relation between structure and thermal conductivity in type-I　clathrates X₈Ga₁₆Ge₃₀ (X = Sr, Ba) based on electrostatic-potential analysis"
Akihiko Fujiwara, Kunihisa Sugimoto, Che-Hsiu Shih, Hiroshi Tanaka, Jun Tang, Yoichi Tanabe, Jingtao Xu, Satoshi Heguri, Katsumi Tanigaki, and Masaki Takata
Physical Review B 85, 144305 (2012), published online 17 April 2012