First-principles study of LaOPbBiS3 and its analogous compounds as thermoelectric materials

Abstract

LaOBiPbS3 is a kind of pnictogen-dichalcogenide layered compounds, which have recently been experimentally investigated as thermoelectric materials owing to their low thermal conductivity and high controllability of constituent elements. However, thermoelectric performance of LaOBiPbS3 is at present not very high and that of its analogous compounds remains to be unknown. In this study, we theoretically investigate thermoelectric properties of 24 possible variations of the constituent elements in LaOBiPbS3 from the viewpoint of the electronic structure. We find that some compounds can have much better thermoelectric performance than LaOBiPbS3; in particular, LaOSbPbSe3 is predicted to have a power factor five times as large as that of LaOBiPbS3. Here, the choice of the pnictogen atom (As, Sb, and Bi), of which the low-energy conduction bands mainly consist, correlates with the calculated power factor and the dimensionless figure of merit, ZT. Such correlation comes from the fact that the low-dimensionality of the electronic structure, which enhances the density of states near the band edge, strongly depends on the pnictogen atom through, e.g., the strength of the spin-orbit coupling. Moreover, hybridization of the wave functions in the pnictogen-dichalcogenide layer and those in the rock-salt layer plays a key role in gap opening, and thus is important for achieving high thermoelectric performance. In LaOSbPbSe3, such hybridization also pushes up the conduction band bottom, which enhances the density of states near the band edge and thus the power factor.