Constructing vortex functions and basis states of Chern insulators: ideal condition, inequality from index theorem, and coherent-like states on von Neumann lattice

TL;DR

This paper develops a theory for constructing vortex functions and basis states of Chern insulators within the tight-binding framework, optimizing their properties, and connecting to topological invariants and coherent state concepts.

Contribution

It introduces a method to construct and optimize vortex functions and basis states for Chern insulators, linking them to index theorems and band topology.

Findings

Optimized vortex functions minimize deviation from ideal Chern insulators.

Constructed basis sets include radially localized and coherent-like states.

Proposed an inequality related to band topology and discussed differences with previous models.

Abstract

In the field of fractional Chern insulators, a great deal of effort has been devoted to characterizing Chern bands that exhibit properties similar to the Landau levels. Among them, the concept of the vortex function, which generalizes the complex coordinate used for the symmetric-gauge Landau-level basis, allows for a concise description. In this paper, we develop a theory of constructing the vortex function and basis states of Chern insulators in the tight-binding formalism. In the first half, we consider the optimization process of the vortex function, which minimizes an indicator that measures the difference from the ideal Chern insulators. In particular, we focus on the sublattice position dependence of the vortex function or the quantum geometric tensor. This degree of freedom serves as a discrete analog of the non-uniformity in the spatial metric and magnetic field in a continuous model. In the second half, we construct two types of basis sets for a given vortex function: radially localized basis set and coherent-like basis set. The former basis set is defined as the eigenstates of an analogy of the angular momentum operator. Remarkably, one can always find exact zero mode(s) for this operator, which is explained by the celebrated Atiyah-Singer index theorem. As a byproduct, we propose an inequality rooted in the band topology. We also discuss the subtle differences between our formalism and the previous works about the momentum-space Landau level. The latter basis set generalizes the concept of coherent states on von Neumann lattice. While this basis set is not orthogonal, it is useful to compare the LLL and the given Chern insulator directly in the Brillouin zone. These basis sets are expected to be useful for many-body calculations of fractional Chern insulators.