Forbidden p-d Orbital Coupling Accelerates High-Power-Factor Materials Discovery

Abstract

The intrinsic entanglement between electrical conductivity (σ) and the Seebeck coefficient (S) significantly constrains power factor (PF) enhancement in thermoelectric (TE) materials. While high valley degeneracy (Nvk) effectively balances σ and S to improve PF, identifying compounds with high Nvk remains challenging. In this study, we develop an effective approach to rapid discover p-type semiconductors with high Nvk through manipulating anion-p and cation-d orbital coupling. By prohibiting p-d orbital coupling at the point, the valence band maximum shifts away from the point (where Nvk=1), thereby increasing Nvk. Through the examination of the common irreducible representations of anion-p and cation-d orbitals at the point, we identify 7 compounds with Nvk 6 from 921 binary and ternary semiconductors. First-principles calculations with electron-phonon coupling demonstrate that PtP2, PtAs2, and PtS2 exhibit exceptionally high PFs of 130, 127, and 82 μWcm-1K-2 at 300K, respectively, which are three to five times higher than those of the well-studied TE materials. This work not only elucidates the underlying mechanism of high Nvk formation through group theory, but also establishes an efficient high-PF material discovery paradigm, extended to more complex systems.