Exactly solvable lattice models for interacting electronic insulators in two dimensions

In the past decade, tremendous efforts have been made towards understanding fermionic symmetry protected topological (FSPT) phases in interacting systems. Nevertheless, for systems with continuum symmetry, e.g., electronic insulators, it is still unclear how to construct an exactly solvable model with a finite dimensional Hilbert space in general. In this paper, we give a lattice model construction and classification for 2D interacting electronic insulators. Based on the physical picture of \(\mathrm{U(1)}_f\)-charge decorations, we illustrate the key idea by considering the well known 2D interacting topological insulator. Then we generalize our construction to an arbitrary 2D interacting electronic insulator with symmetry \(G_f=\mathrm{U(1)}_f \rtimes_{\rho_1,\omega_2} G\), where \(\mathrm{U(1)}_f\) is the charge conservation symmetry and \(\rho_1, \omega_2\) are additional data which fully characterize the group structure of \(G_f\). Finally we study more examples, including the full interacting classification of 2D crystalline topological insulators.