Quantum loops in the 1T transition metal dichalcogenides

Abstract

Loop arrangements and their quantum superpositions describe several interesting many-particle states. We propose that they also describe bonding in a class of transition metal dichalcogenides. We present an effective quantum loop model for monolayers with 1T structure and a d2 valence electron configuration: materials of the form MX2 (M = Mo, W and X=S, Se, Te) and AM'Y2 (A = Li, Na; M' = V, Nb and Y = O, S, Se). Their t2g orbitals exhibit strongly directional overlaps between neighbouring atoms, favouring the formation of valence bonds. A transition metal atom forms two valence bonds, each with one of its neighbours. When connected, these bonds form loops that cover the triangular lattice. We construct a minimal Rokhsar-Kivelson-like model with resonance processes that cut and reconnect loops that run in proximity. The resulting dynamics is more constrained than in traditional quantum dimer models, with a `bending' constraint that arises from orbital structure. In the resulting phase diagram, we find phases that resemble distorted phases seen in materials, viz., the 1T' and trimerized phases. As a testable prediction, we propose that a single d1 or d3 impurity will terminate a loop and give rise to a long-ranged texture. For example, a Ti/Cr defect in LiVO2 will produce one or more domain walls that propagate outward from the impurity. We discuss the possibility of a loop liquid phase that can emerge in these materials.