SUPA, School of Physics and Astronomy, University of Glasgow , Glasgow G12 8QQ, U.K.
CNRS, ICMCB, UPR 9048 , F-33600 Pessac, France.
ACS Appl Mater Interfaces. 2018 Feb 7;10(5):4786-4793. doi: 10.1021/acsami.7b14525. Epub 2018 Jan 25.
Half-Heusler alloys based on TiNiSn are promising thermoelectric materials characterized by large power factors and good mechanical and thermal stabilities, but they are limited by large thermal conductivities. A variety of strategies have been used to disrupt their thermal transport, including alloying with heavy, generally expensive, elements and nanostructuring, enabling figures of merit, ZT ≥ 1 at elevated temperatures (>773 K). Here, we demonstrate an alternative strategy that is based around the partial segregation of excess Cu leading to grain-by-grain compositional variations, the formation of extruded Cu "wetting layers" between grains, and-most importantly-the presence of statistically distributed interstitials that reduce the thermal conductivity effectively through point-defect scattering. Our best TiNiCuSn (y ≤ 0.1) compositions have a temperature-averaged ZT = 0.3-0.4 and estimated leg power outputs of 6-7 W cm in the 323-773 K temperature range. This is a significant development as these materials were prepared using a straightforward processing method, do not contain any toxic, expensive, or scarce elements, and are therefore promising candidates for large-scale production.
基于 TiNiSn 的半 Heusler 合金是很有前途的热电材料,具有较大的功率因子和良好的机械及热稳定性,但它们的热导率较大。人们采用了各种策略来破坏其热传输,包括与重元素(通常是昂贵的元素)合金化和纳米结构化,从而使在较高温度(>773 K)下的品质因数 ZT≥1 成为可能。在这里,我们展示了一种替代策略,其基于过量 Cu 的部分偏析,导致晶粒间的成分变化,形成晶间挤出的 Cu“润湿层”,最重要的是——存在统计分布的间隙原子,通过点缺陷散射有效地降低热导率。我们最好的 TiNiCuSn(y≤0.1)成分在 323-773 K 温度范围内的平均 ZT 值为 0.3-0.4,估计腿部功率输出为 6-7 W cm。这是一个重要的发展,因为这些材料是使用简单的处理方法制备的,不包含任何有毒、昂贵或稀缺的元素,因此是大规模生产的有前途的候选材料。
