Janus Effect of Phonons in Inducing Diffusons in Nanolayered XMg<sub>2</sub>Bi<sub>2</sub> (X = Sr, Ba): Static–Dynamic Transition for Cations
Pengfei Zhang, Shuwei Tang, Da Wan, Peng Ai, T. F. Zheng, T. Yan, Yujie Bao, Yufei Meng, Shulin Bai
Abstract
The thermoelectric performance of XMg 2 Bi 2 (X = Sr, Ba) materials is systematically investigated through integrated first-principles calculations, Boltzmann transport theory, and a two-channel model in this work. The temperature-activated static–dynamic transition in X (X = Sr, Ba) atoms vibrations induces a Janus effect of phonons, facilitating dual phonon transport regimes characterized by normal phonon and diffusons. The comparable ionicity between X 2+ (X = Sr, Ba) and [Mg 2 Bi 2 ] 2– layers disrupts the conventional Zintl-phase characteristics, leading to an atypically isotropic lattice thermal conductivity within their materials. Concurrently, charge-insulating X 2+ (X = Sr, Ba) layers restrict out-of-plane carrier mobility, creating a distinctive two-dimensional (2D) electronic transport framework superimposed on three-dimensional (3D) phonon dynamics. By disentanglement of the cross-dimensional transport phenomena through a two-channel model and multicarrier scattering analysis, the XMg 2 Bi 2 (X = Sr, Ba) materials achieve remarkable thermoelectric performance with the optimal figure of merits ( ZT max ) of 1.5 ( p -type) and 1.9 ( n -type) at 600 K, respectively.