Cluster Gutzwiller method for bosonic lattice systems

TL;DR

The paper introduces a versatile, computationally efficient cluster Gutzwiller method that accurately predicts phase diagrams and quantum fluctuations in bosonic lattice models, outperforming mean-field approaches and adaptable to complex systems.

Contribution

It presents a new cluster Gutzwiller approach that improves quantum fluctuation descriptions and can be applied to various complex bosonic lattice systems.

Findings

Accurately predicts superfluid to Mott-insulator transition points.

Achieves results comparable to quantum Monte-Carlo for large clusters.

Flexible application to disordered, superlattice, and extended Hubbard models.

Abstract

A versatile and numerically inexpensive method is presented allowing the accurate calculation of phase diagrams for bosonic lattice models. By treating clusters within the Gutzwiller theory, a surprisingly good description of quantum fluctuations beyond the mean-field theory is achieved approaching quantum Monte-Carlo predictions for large clusters. Applying this powerful method to the Bose-Hubbard model, we demonstrate that it yields precise results for the superfluid to Mott-insulator transition in square, honeycomb, and cubic lattices. Due to the exact treatment within a cluster, the method can be effortlessly adapted to more complicated Hamiltonians in the fast progressing field of optical lattice experiments. This includes state- and site-dependent superlattices, large confined atomic systems and disordered potentials, as well as various types of extended Hubbard models. Furthermore, the approach allows an excellent treatment of systems with arbitrary filling factors. We discuss the perspectives that allow for the computation of large, spatially-varying lattices, low-lying excitations, and time evolution.