A material catalogue with glass-like thermal conductivity mediated by crystallographic occupancy for thermoelectric application

Discovering materials with intrinsically low lattice thermal conductivityκ_latis an important route for achieving high thermoelectric performance. In reality, the conventional synthetic approach, however, relies on trial and error. Herein, we proposed a new crystallographic parameter, namely the site occupancy factor, as an effective indicator to identify a material catalogue with lowκ_lat. Taking Cu₆Te₃S, in which some Cu atoms show partial occupancy, as the representative sample, it was found that this compound exhibited ultralowκ_latwith weak temperature dependence from 5 K to 350 K. The appearance of a boson peak and unusual two-level tunneling states in the heat capacity measurement revealed the low-lying optical modes and dynamic diffusion disorder, respectively. This glass-like thermal property in a crystalline material arose from the combination of the anharmonic and anisotropic vibration of the Cu atom, the ionic bond feature around the Cu atom, and the global weak bonding, confirmed by the calculated phonon dispersion, electron localization function, and potential energy curves. Utilizing the proposed indicator of partial occupancy, we searched in the Crystallography Open Database for further potential candidate materials with lowκ_lat. As a further test of the efficacy of this strategy, two unearthed compounds were synthesized and both were indeed found to exhibit very lowκ_lat, around 0.6 W m⁻¹K⁻¹at 300 K.