We have given an outline of our previous and on-going works related to naturally nanostructured thermoelectric oxides. One example is that buildup of different “nano-blocks” is effective to produce noble thermoelectric property as the intrinsic structure of thermoelectric materials. Co 3Co 4O 9 and Bi 2Sr 2Co 2O 9 have intriguing crystal structure consisting of two blocks, such as CoO 2 sub-lattice, and Ca 2CoO 3 and Bi 2Sr 2O 4 sub-lattice, respectively. Once these two blocks are built up as “nano-blocks” in about 1.1–1.5 nm scale corresponding to the c-cell parameter, high dimensionless figure of merit ZT of ca. 1.1 at 973 K emerged in a single crystal of Co 3Co 4O 9 and Bi 2Sr 2Co 2O 9 by harmony of the function of each part. However, power density of thermoelectric generation is 1–10 W/cm 3 against device volume, so that bulk devices are indispensable for thermoelectric power application to generate kW or higher class output. The next challenge is to produce naturally nanostructure-controlled bulk oxides. ZnMnGaO 4 and Co 1.5Mn 1.5O 4 were taken as a model case for constructing a self-assembled nanostructure. By utilization of spinodal decomposition, these oxides have naturally formed characteristics nanostructures, such as nanochckerboard and twin-related domains, leading to low thermal conductivity of these oxides. This result would open up a possibility for realization of bulk oxides with high thermoelectric properties by nanostructure production via self organization.
CITATION STYLE
Funahashi, R., & Kosuga, A. (2013). Naturally Nanostructured Thermoelectric Oxides. In Springer Series in Materials Science (Vol. 182, pp. 353–363). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-3-642-37537-8_15
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