Synergistic Effect of Band and Nanostructure Engineering on the Boosted Thermoelectric Performance of n-Type Mg₃₊(Sb, Bi)₂ Zintls

Thermoelectric Mg-3+(delta)(Sb, Bi)(2) Zintls have attracted significant attention because of their high-performing, eco-friendly, and cost-effective features, but their thermoelectric properties still need improvement for application to practical devices. Here an outstanding ZT of approximate to 1.87 at 773 K and a high average ZT of approximate to 1.2 in n-type Y-doped Mg3.2Sb1.5Bi0.49Se0.01 are reported, both of which rank as top values among the reported literature. First-principles calculations indicate that substituting the Mg site with Y shifts the Fermi level into the conduction band and simultaneously narrows the bandgap, both strengthening the n-type semiconducting feature and boosting the electron carrier density of Mg3.2Sb1.5Bi0.49Se0.01. A high power factor of approximate to 21.4 mu W cm(-1) K-2 is achieved at 773 K in Mg3.18Y0.02Sb1.5Bi0.49Se0.01, benefiting from the rationally tuned carrier density of approximate to 7.7 x 10(19) cm(-3) at this temperature. In addition, the doped Ys act as point defects to cause significant lattice distortions and strains, confirmed by comprehensive micro/nanostructure characterizations. These lattice imperfections suppress the lattice thermal conductivity to approximate to 0.41 W m(-1) K-1 at 773 K, leading to such a high ZT. Furthermore, a high energy conversion efficiency of approximate to 13.8% is predicted by a temperature gradient of 450 K, indicating a great potential to be applied to practical devices for mid-temperature applications.