%0 Journal Article
%T Self©\Tuning n©\Type Bi2(Te,Se)3/SiC Thermoelectric Nanocomposites to Realize High Performances up to 300 ˇăC
%A Chao©\Feng Wu
%A Fu©\Hua Sun
%A G. Jeffrey Snyder
%A Thomas C. Chasapis
%A Umut Aydemir
%A Yu Pan
%J Archive of "Advanced Science".
%D 2017
%R 10.1002/advs.201700259
%X Bi2Te3 thermoelectric materials are utilized for refrigeration for decades, while their application of energy harvesting requires stable thermoelectric and mechanical performances at elevated temperatures. This work reveals that a steady zT of ˇÖ0.85 at 200 to 300 ˇăC can be achieved by doping small amounts of copper iodide (CuI) in Bi2Te2.2Se0.8¨Csilicon carbide (SiC) composites, where SiC nanodispersion enhances the flexural strength. It is found that CuI plays two important roles with atomic Cu/I dopants and CuI precipitates. The Cu/I dopants show a self©\tuning behavior due to increasing solubility with increasing temperatures. The increased doping concentration increases electrical conductivity at high temperatures and effectively suppresses the intrinsic excitation. In addition, a large reduction of lattice thermal conductivity is achieved due to the ˇ°in situˇ± CuI nanoprecipitates acting as phonon©\scattering centers. Over 60% reduction of bipolar thermal conductivity is achieved, raising the maximum useful temperature of Bi2Te3 for substantially higher efficiency. For module applications, the reported materials are suitable for segmentation with a conventional ingot. This leads to high device ZT values of ˇÖ0.9¨C1.0 and high efficiency up to 9.2% from 300 to 573 K, which can be of great significance for power generation from waste heat
%K bismuth©\telluride©\selenide
%K device figure of merit
%K self©\tuning
%K thermoelectrics
%U https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5700642/