Strategic Optimization of the Electronic Transport Properties of Pseudo-Ternary Clathrates

While alloying is a powerful handle for materials engineering, it is an ongoing challenge to navigate the large and complex parameter space of these materials. This applies in particular for thermoelectrics and even more so clathrates. Here, a combination of density functional theory calculations, alloy cluster expansions, Monte Carlo simulations, and Boltzmann transport theory calculations is used to identify compositions that yield high power factors in the pseudo-ternary clathrates Ba8AlxGayGe46-x-y and Ba8GaxGeySi46-x-y, while accounting for weight and raw material costs. The results show how a cost-efficient performance can be achieved by reducing the number of Al and Ga atoms per unit cell, while compensating the resulting increase in the carrier concentration via an extrinsic dopant. The approach used in this study is transferable and can be a useful tool for mapping the thermodynamic and transport properties of other multinary systems.

Automated summary

The study used a combination of theoretical and computational simulation methods to explore compositions with high power factors in clathrates, considering cost factors. The results showed that cost-effective performance can be achieved by reducing the number of Al and Ga atoms, while using extrinsic dopants.