Insights into the structural complexity and local disorder of crystalline AsTe3 from semi-automated first-principles modelling

Abstract

A semi-automated workflow relying on atomic-scale modelling is introduced to explore and understand the yet-unsolved structure of the crystalline AsTe₃ material, recently obtained from crystallization of the parent AsTe₃ glass, which shows promising properties for thermoelectric applications. The seemingly complex crystal structure of AsTe₃ is investigated with density functional theory, from the stand point of As/Te disorder, in a structural template derived from elemental-Te (Te_el), following experimental findings from combined X-ray total scattering and diffraction. Our workflow includes a combinatorial structure generation step followed by successive structure selection and relaxation steps with progressively-increasing accuracy levels and a multi-criterion evaluation procedure. A small set of high quality models with common structural features emerge, all consisting of intergrowth domains typically below 1 nm in thickness and with the local compositions and structures of Te_el and α-As₂Te₃, but with different thicknesses and relative arrangements, which points to the presence of such defects in crystalline AsTe₃. While predictions of the electronic bandgaps are in excellent agreement with the experimental value for our best models, we find that some of these defects may be associated with the locally-increased density of states around the Fermi level, potentially contributing to the overall electronic conductivity, which, along with intrinsic structural complexity, is among the key features of the reported outstanding thermoelectric properties of this compound.