Effects of Ir Substitution and Processing Conditions on Thermoelectric Performance of p-Type Zr sub(0.5)Hf sub(0.5)Co sub(1-x)Ir sub(x)Sb sub(0.99)Sn sub(0.01) Half-Heusler Alloys

A series of samples with the composition Zr sub(0.5)Hf sub(0.5)Co sub(1-x)Ir sub(x)Sb sub(0.99)Sn sub(0.01)(x = 0.0 to 0.7) were synthesized by high-temperature solid-state reaction at 1173 K High-density pellets of the powders were obtained using hot press (HP) and spark plasma sintering (SPS) techniques. The thermoelectric properties of the pellets were measured from 300 K to 750 K. Independently of the pressing conditions, all Ir-containing samples (x > 0) showed p-type semiconducting behavior. At 300 K, the electrical conductivity and thermopower of Zr sub(0.5)Hf sub(0.5)Co sub(1-x)Ir sub(x)Sb sub(0.99)Sn sub(0.01) materials surprisingly increased with increasing Ir concentration. The largest electrical conductivity and thermopower values of 150 S/cm and 140 mu V/K, respectively, were observed at 300 K for x = 0.7. The thermal conductivity of the synthesized materials decreased with increasing Ir content, went through a minimum value (x = 0.3), and increased thereafter with further addition of Ir. Pellets fabricated by SPS showed smaller thermal conductivity than pellets of the same composition obtained from uniaxial hot pressing. A thermal conductivity value of similar to 2.0 W/m K was observed at 300 K for an SPS pellet with the composition Zr sub(0.5)Hf sub(0.5)Co sub(1-x)Ir sub(x)Sb sub(0.99)Sn sub(0.01). The thermal conductivity of Zr sub(0.5)Hf sub(0.5)Co sub(1-x)Ir sub(x)Sb sub(0.99)Sn sub(0.01) decreased with rising temperature, and the smallest value of similar to 1.5 W/m K was observed at 750 K for the SPS specimen with x = 0.5.