Atomistic origin of low thermal conductivity in quaternary chalcogenides Cu(Cd, Zn)2InTe4
Abstract
Crystalline semiconductors with intrinsically low lattice thermal conductivity (K) are vital for device applications such as barrier coatings and thermoelectrics. Quaternary chalcogenide semiconductors such as CuCd2InTe4 and CuZn2InTe4 are experimentally shown to exhibit low K, yet its microscopic origin remains poorly understood. Here, we analyse their thermal transport mechanisms using a unified first-principles framework that captures both the Peierls (particle-like propagation, KP) and coherence (wave-like tunneling, KC) mechanisms of phonon transport. We show that extended antibonding states below the Fermi level lead to enhanced phonon anharmonicity and strong scattering of heat-carrying phonon modes, suppressing K in these chalcogenides. We show that KP dominates the total thermal conductivity, while KC remains negligible even under strong anharmonicity of the phonon modes. The heavier Cd ions in CuCd2InTe4 induce greater acoustic-optical phonon overlap and scattering compared to CuZn2InTe4, further lowering thermal conductivity of the former. Additionally, grain boundary scattering in realistic samples contributes to further suppression of thermal transport. Our findings establish the atomistic origins of low K in quaternary chalcogenides and offer guiding principles for designing low-thermal-conductivity semiconductors.
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