Strong Intra- and Interchain Orbital Coupling Leads to Multiband and High Thermoelectric Performance in Na2AuX (X = P, As, Sb, and Bi)

Abstract

The intrinsic coupling among electrical conductivity (σ), Seebeck coefficient (S), and lattice thermal conductivity (L) imposes a fundamental limit on the dimensionless figure of merit ZT in thermoelectric (TE) materials. Increasing band degeneracy can effectively balance σ and S, enabling a high power factor (PF, S2σ). However, compounds with intrinsically large band degeneracy are scarce. Here, we present an unconventional strategy to realize elevated band degeneracy in zigzag-chain Na2AuX (X = P, As, Sb, Bi) compounds by harnessing strong intra- and interchain orbital coupling. Pronounced hybridization between Au-dz2 and X-pz orbitals along the Au--X zigzag chains, together with unexpectedly strong interchain X-px/py coupling, produces a highly dispersive, multivalley valence band structure that supports an exceptional PF. Concurrently, the intrinsically weak interchain interactions arising from the quasi-one-dimensional framework, together with the weakened Au--X and Au--Au bonds within the chains due to filling of p-d* antibonding states, result in an ultralow L. First-principles calculations combined with Boltzmann transport theory predict that p-type Na2AuBi achieves a PF of 63.9\,μW\,cm-1\,K-2, an ultralow L of 0.49\,W\,m-1\,K-1, and a maximum ZT of 4.7 along the zigzag-chain direction at 800\,K. This work establishes a new design paradigm for high-efficiency TE materials by exploiting substantial orbital overlap in structurally weakly bonded, quasi-one-dimensional systems, opening promising avenues for the discovery and engineering of next-generation high-performance TE materials.

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