P-type Tetrahedrite from mineral waste
Within the START project, MBN has developed an advanced p-type thermoelectric powder based on the tetrahedrite compound Cu₁₂₋ₓ(TM)ₓSb₄S₁₃ (TM = Fe, Zn). Tetrahedrites are copper-based sulfide minerals valued for their low thermal conductivity, use of earth-abundant and non-toxic elements, and strong potential in sustainable energy conversion. Through dual substitution of Cu with Fe and Zn, MBN’s material achieves optimised carrier concentration, delivering a thermoelectric figure of merit (ZT) > 1 with peak efficiency near 350 °C.
Produced via the proprietary Mechanomade® process, this zero-waste solid-state synthesis ensures homogeneous phases and precise control over composition. Consolidation by Spark Plasma Sintering (SPS) yields dense, fine-grained legs with high electrical conductivity, low thermal conductivity, and robust mechanical integrity.
COMPOSITION
COPPER [ bal. ] ANTIMONY [ 30% ] SULPHUR [ 25% ] ZINC [ 2% ] IRON [ 1.7% ]
PROPERTIES
SEEBECK COEFFICIENT [ 240–250 μV/K ] ELECTRICAL RESISTIVITY [ 55–60 μΩ·m ] THERMAL CONDUCTIVITY [ 0.6 W/mK ] ZT [ 1.1 ] POWER FACTOR [ 1 mW/mK² ]
Within the START project, MBN has developed an advanced p-type thermoelectric powder based on the tetrahedrite compound Cu₁₂₋ₓ(TM)ₓSb₄S₁₃ (TM = Fe, Zn). Tetrahedrites are copper-based sulfide minerals valued for their low thermal conductivity, use of earth-abundant and non-toxic elements, and strong potential in sustainable energy conversion. Through dual substitution of Cu with Fe and Zn, MBN’s material achieves optimised carrier concentration, delivering a thermoelectric figure of merit (ZT) > 1 with peak efficiency near 350 °C.
