Effect of hydrostatic pressure and alloying on thermoelectric properties of van der Waals solid KMgSb: An ab-initio study

Abstract

Through a combined first-principles and Boltzmann transport theory, we systematically investigate the thermal and electrical transport properties of the unexplored ternary quasi two-dimensional KMgSb system of KMgX (X = P, As, Sb, and Bi) family. Herein, the transport properties of KMgSb under the application of hydrostatic pressure and alloy engineering are reported. At a carrier concentration of 8×1019~cm-3, the figure of merit zT (0.75) for both the n-type and p-type of KMgSb closely matched, making it an attractive option for engineering both legs of a thermoelectric device using the same material. This is particularly desirable for high-performance thermoelectric applications. Furthermore, the zT value increases as pressure decreases, further enhancing its potential for use in thermoelectric devices. In the case of substitutional doping (replacing 50 \% Sb by Bi atom), we observed 49~\% (in-plane) increase in the peak thermoelectric figure of merit (zT). The maximum zT value obtained after alloy engineering is 1.45 at 900~K temperature. Hydrostatic pressure is observed to be a great tool to tune the lattice thermal conductivity (L). We observed that the negative pressure-like effects could be achieved by chemically doping bigger-size atoms, especially when L is a property under investigation. Through our computational investigation, we explain that hydrostatic pressure and alloy engineering may improve thermoelectric performance dramatically.