Spin susceptibility anomaly in cluster Mott insulators on a partially-filled anisotropic Kagome lattice: applications to LiZn2Mo3O8

TL;DR

This paper investigates cluster Mott insulators on an anisotropic Kagome lattice, revealing novel quantum spin liquid states with unique charge and spin excitations, and explains anomalous spin susceptibility in LiZn2Mo3O8.

Contribution

It introduces a new class of cluster Mott insulators with plaquette charge order and analyzes their spin and charge excitations, connecting theory to experimental observations in LiZn2Mo3O8.

Findings

Cluster Mott insulators can host U(1) quantum spin liquids with spinon Fermi surfaces.

A novel cluster Mott insulator with plaquette charge order modifies spinon excitations.

Finite-temperature spin susceptibility anomalies in LiZn2Mo3O8 can be explained by these cluster Mott states.

Abstract

Motivated by recent experiments on the quantum-spin-liquid candidate material LiZn2Mo3O8, we study a single-band extended Hubbard model on an anisotropic Kagome lattice with the 1/6 electron filling. Due to the partial filling of the lattice, the inter-site repulsive interaction is necessary to generate Mott insulators, where electrons are localized in clusters, rather than at lattice sites. We provide examples of such cluster Mott insulators and study the phase transitions between metallic states and cluster Mott insulators on an anisotropic Kagome lattice. It is shown that these cluster Mott insulators are generally U(1) quantum spin liquids with spinon Fermi surfaces. However, the nature of charge excitations in different cluster Mott insulators could be quite different and we show that there exists a novel cluster Mott insulator where charge fluctuations around the hexagonal cluster induce a plaquette charge order (PCO). The spinon excitation spectrum in this spin-liquid cluster Mott insulator is reconstructed due to the PCO so that only 1/3 of the total spinon excitations are magnetically active. The strong coupling limit of the same model is also analyzed via a Kugel-Khomskii-like model. Based on these results, we propose that the anomalous behavior of the finite-temperature spin-susceptibility in LiZn2Mo3O8 may be explained by finite-temperature properties of the cluster Mott insulator with the PCO as well as fractionalized spinon excitations. Existing and possible future experiments on LiZn2Mo3O8, and other Mo-based cluster magnets are discussed in light of these theoretical predictions.