Thermoelectric composite with enhanced figure of merit via interfacial doping

Michael J. Adams, Joseph P. Heremans
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引用次数: 8

Abstract

In order to improve the thermoelectric conversion efficiency and figure of merit, ZT, composite materials of organic or inorganic constituents often are considered. The limitation of this approach is set by the effective medium theory, which states that the ZT in a composite material cannot exceed the greatest value of any single constituent, if the constituents do not interact. Here, we describe a method that circumvents this limit, based on the introduction of interfacial doping. An electrically and thermally insulating medium is distributed into a conventional thermoelectric host material but is coated with an aliovalent acceptor that is allowed to diffuse locally into the host matrix, thereby doping it locally. The thermal conductivity decreases when the insulating material is added, but the more electrically conducting region around the insulator prevents an equally large increase in electrical resistivity. Employing this method in p-type (Bi1-xSbx)2Te3 compounds results in a maximum figure of merit zT?=?1.3, an over 10% improvement compared to the host material alone. We report synthesis and measurement techniques in addition to thermoelectric transport properties. While we report on one material system, the concept is not specific to that system and may be used to provide functionality in other thermoelectric composites.

Abstract Image

界面掺杂增强性能系数的热电复合材料
为了提高热电转换效率和性能系数,经常考虑有机或无机成分的复合材料ZT。这种方法的局限性是由有效介质理论设定的,该理论指出,如果成分不相互作用,复合材料中的ZT不能超过任何单一成分的最大值。在这里,我们描述了一种绕过这一限制的方法,基于引入界面掺杂。将电和热绝缘介质分布到传统的热电宿主材料中,但涂有一层共价受体,允许其局部扩散到宿主基质中,从而局部掺杂。当添加绝缘材料时,导热系数降低,但绝缘体周围的导电区域阻止了电阻率的同样大的增加。在p型(Bi1-xSbx)2Te3化合物中采用该方法得到的最大性能值zT = 1.3,与单独的主体材料相比提高了10%以上。除了热电输运性质外,我们还报告了合成和测量技术。虽然我们报告了一种材料系统,但该概念并不特定于该系统,并且可以用于其他热电复合材料中提供功能。
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