Evolution of Phonon Transport Across Structural Phase Transitions in MgAgSb
Abstract
MgAgSb, a promising thermoelectric material, undergoes reversible phase transitions that drastically alter its thermal transport behavior. Using first-principles calculations, we systematically investigate the lattice thermal conductivity (L) of its three phases: α, β, and γ, revealing a progressive increase following α < β < γ. This trend originates from distinct scattering mechanisms. Four-phonon scattering substantially suppresses the particle-like conductivity (p) in the β and γ phases, while electron-phonon scattering provides a minor additional reduction. In contrast, the wave-like conductivity (c) from coherent phonon tunneling is highest in the complex α phase, contributing up to 44\% of L. Notably, the temperature dependence of L differs fundamentally between phases: in β, the weak p variation arises from a decreasing Gr\"uneisen parameter with temperature; in α, the strong rise in c with temperature counteracts the decay of p. Our findings establish a comprehensive picture of thermal transport in MgAgSb, highlighting the phase-dependent interplay between particle-like and wave-like phonon contributions.
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