Modeling the Superlattice Phase Diagram of Transition Metal Intercalation in Bilayer 2H-TaS2

Abstract

Van der Waals hosts intercalated with transition metal (TM) ions exhibit a range of magnetic properties strongly influenced by the structural order of the intercalants. However, predictive computational models for the intercalant ordering phase diagram are lacking, complicating experimental pursuits to target key structural phases. Here we use Density Functional Theory (DFT) to construct a pairwise lattice model and Monte Carlo to determine its associated thermodynamic phase diagram. To circumvent the complexities of modeling magnetic effects, we use the diamagnetic ions Zn2+ and Sc3+ as computationally accessible proxies for divalent and trivalent species of interest (Fe2+ and Cr3+), which provide insights into the high-temperature thermodynamic phase diagram well above the paramagnetic transition temperature. We find that electrostatic coupling between intercalants is almost entirely screened, so the pairwise lattice model represents a coarse-grained charge density reorganization about the intercalated sites. The resulting phase diagram reveals that the entropically-favored 3 × 3 ordering and coexisting locally ordered 3 × 3 and 2 × 2 domains persist across a range of temperatures and intercalation densities. This occurs even at quarter filling of interstitial sites (corresponding to bulk stoichiometries of M0.25TaS2; M = intercalant ion) where a preference for long-range 2 × 2 order is typically assumed.

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