Thermoelectric materials constitute an alternative source of sustainable energy, harvested from waste heat. Bi2Te3 is the most utilized thermoelectric alloy. We show that it can be readily prepared in nanostructured form by arc-melting synthesis, yielding mechanically robust pellets of highly oriented polycrystals. This material has been characterized by neutron powder diffraction (NPD), scanning electron microscopy (SEM), and electronic and thermal transport measurements. A microscopic analysis from NPD data demonstrates a near-perfect stoichiometry of Bi2Te3 and a fair amount of anharmonicity of the chemical bonds. The as-grown material presents a metallic behavior, showing a record-low resistivity at 320 K of 2 μΩ m, which is advantageous for its performance as a thermoelectric material. SEM analysis shows a stacking of nanosized sheets, each of them presumably single-crystalline, with large surfaces perpendicular to the c crystallographic axis. This nanostructuration notably affects the thermoelectric properties, involving many surface boundaries that are responsible for large phonon scattering factors, yielding a thermal conductivity as low as 1.2 W m−1 K−1 around room temperature.
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机译:热电材料是从废热中收集的可持续能源的替代来源。 Bi2Te3是最常用的热电合金。我们表明,它可以很容易地通过电弧熔化合成以纳米结构形式制备,从而产生高度定向的多晶机械坚固的颗粒。该材料的特征在于中子粉末衍射(NPD),扫描电子显微镜(SEM)以及电子和热传输测量。 NPD数据的微观分析表明,Bi2Te3的化学计量接近完美,化学键的非谐性相当高。所生长的材料表现出金属行为,在320K时显示2μΩm的创纪录低电阻率,这有利于其作为热电材料的性能。 SEM分析显示了纳米片的堆叠,每个片大概是单晶的,其大表面垂直于c晶轴。这种纳米结构会显着影响热电性能,涉及许多导致大声子散射因子的表面边界,从而产生低至1.2W·m -1 K -1 的热导率。在室温附近。
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