Wilson-Loop-Ideal Bands and General Idealization
Abstract
Quantum geometry is universally bounded from below by Wilson-loop windings. In this work, we define an isolated set of bands to be Wilson-loop-ideal, if their quantum metric saturates the Wilson-loop lower bound. The definition naturally incorporates the known Chern-ideal and Euler-ideal bands, and allows us to define other types of ideal bands, such as Kane-Mele -ideal and inversion-fragile-ideal bands. In particular, we find that in the case of zero total Chern number, an isolated WL-ideal set of two bands with non-singular nonabelian Berry curvature and nontrivial normal Wilson-loop winding always admits a Chern-ideal gauge, without the need of a global good quantum number (such as spin). This enables the direct construction of new topologically ordered states, such as fractional topological insulator wavefunctions. We further propose a general framework of constructing monotonic flows that achieve Wilson-loop-ideal states starting from non-ideal bands through band mixing, where Wilson-loop-ideal states are not energy eigenstates but have smooth projectors similar to isolated bands. We apply the constructed flows to the realistic model of twisted bilayer MoTe, a moir\'e Rashba model and another moir\'e time-reversal-breaking models, and numerically find Chern-ideal, -ideal and inversion-fragile states, respectively, with relative error in the integrated quantum metric below . Our exact-diagonalization calculations on the numerically ideal states demonstrate the potential of our general definition of Wilson-loop-ideal bands and general procedure of constructing Wilson-loop-ideal states for future study of novel correlated physics.
Cite
@article{arxiv.2509.05410,
title = {Wilson-Loop-Ideal Bands and General Idealization},
author = {Awwab A. Azam and Biao Lian and Shinsei Ryu and Jiabin Yu},
journal= {arXiv preprint arXiv:2509.05410},
year = {2026}
}
Comments
9+28 pages, 2+7 figures