High‐Performance CaMg<sub>2</sub>Bi<sub>2</sub>‐Based Thermoelectric Materials Driven by Lattice Softening and Orbital Alignment via Cadmium Doping
Ming Liu, Muchun Guo, Jianbo Zhu, X. L. Zeng, Hong Chen, Donglin Yuan, Qinyong Zhang, Fanggong Cai, Fengkai Guo, Yuke Zhu, Xingyan Dong, Wei Cai, Yongsheng Zhang, Yuan Yu, Jiehe Sui
Abstract
Abstract Zintl compounds such as n‐type Mg 3 (Sb,Bi) 2 show promising thermoelectric applications benefiting from their high valley degeneracy and low lattice thermal conductivity. However, the heavier p‐type A Mg 2 X 2 ( A = Ca, and Yb; X = Bi and Sb) Zintl counterparts even exhibit a higher κ lat due to strong chemical bonding. Reducing κ lat of A Mg 2 X 2 is an important route for improving thermoelectric performance. Herein, it is found that Cd doping at the Mg site in CaMg 2 Bi 2 can weaken intralayer covalent bonds and soften acoustic phonons, as well as fill the optical phonon gap. These effects result in large atomic displacement, low phonon group velocity, and strong lattice vibration anharmonicity. Doping 10% Cd leads to a reduction of 56% in the κ lat of CaMg 2 Bi 2 . Moreover, Cd doping promotes orbital alignment and thus increases the density‐of‐states effective mass and Seebeck coefficient. Eventually, in conjunction with carrier concentration optimization by Na doping and band structure engineering by Ba doping, a high ZT of ≈1.3 at 873 K in (Ca 0.85 Ba 0.15 ) 0.995 Na 0.005 Mg 1.85 Cd 0.15 Bi 2 sample is realized. This work highlights the significant role of manipulating chemical bonding in suppressing phonon propagation of semiconductors.