Thermoelectric properties of ternary and Al-containing quaternary Ru1−xRexSiy chimney–ladder compounds

Abstract

The thermoelectric properties of ternary and Al-containing quaternary Ru1−xRexSiy chimney–ladder phases have been studied as a function of the Re concentration with the use of directionally solidified alloys. The Ru1−xRexSiy chimney–ladder phases exhibit n- and p-type semiconducting behaviors, respectively, at low and high Re concentrations, at which the X(=Si)/M(=Ru+Re) ratios are respectively, larger and smaller than those expected from the VEC (valence electron concentration)=14 rule. The absolute values of both Seebeck coefficient and electrical resistivity increase as the extent of the deviation from the VEC=14 rule increases, i.e. as the alloy composition deviates from that corresponding to the p–n transition (x≈0.5), indicating that the carrier concentration can be controlled by changing the extent of compositional deviation from the ideal VEC=14 composition. The highest values of the dimensionless figure of merit obtained are 0.47 for ternary (x=0.60) and 0.56 for Al-containing quaternary alloys. The reasons for the systematic compositional deviation from the ideal VEC=14 compositions observed for a series of chimney–ladder phases are discussed in terms of atomic packing.