Thermal conductivity of skutterudite CoSb 3 from first principles: Substitution and nanoengineering effects

Abstract

CoSb 3-based skutterudites are promising intermediate-temperature thermoelectric materials and fundamental understanding of the thermal transport in CoSb3 is crucial for further improving its performance. We herein calculate the lattice thermal conductivity kL of CoSb 3 with first-principles methods and conduct a comprehensive analysis on phonon mode contribution, relaxation time and mean free path (MFP) distributions. The contribution of optical phonons is found to be significant (28% at 300 K) and important optical modes usually involve two or more pnicogen atoms moving synchronously. The MFP (∼135 nm at 300 K) corresponding to 50% kL accumulation in CoSb 3 is much larger than that predicted from the kinetic theory (∼4 nm), providing an opportunity to reduce kL by nanoengineering. The effects of elemental substitution and nanoengineering on kL are therefore investigated. A 10% substitution of Sb by As results in 57% reduction of kL while the in-plane (cross-plane) kL of a 50-nm CoSb 3 thin film is only 56% (33%) of the bulk kL at 300 K. The impurity scattering and boundary scattering mainly suppress phonons in different frequency regimes. By combining these two effects, kL can be reduced by more than 70% at 300 K, potentially leading to much improved ZT near room temperature.