Localization and Flat Bands in Edge-Inflated Lattices

TL;DR

This paper investigates how edge inflation in various lattices leads to flat bands and localization phenomena, analyzing their robustness under disorder and randomness, and identifying geometry-driven localization mechanisms.

Contribution

It introduces new classes of flat bands in edge-inflated lattices and examines their stability under different types of disorder and randomness.

Findings

Flat bands arise from chain-induced, symmetry-protected, and junction mechanisms.

Zero-energy flat bands and junction bands remain robust under certain perturbations.

Flat-band features persist even in randomly edge-inflated graphs without translational symmetry.

Abstract

We study localization and flat-band formation in lattices generated by repeated edge inflation of square, honeycomb, and triangular parent lattices. Replacing each bond by a finite tight-binding chain produces several distinct classes of flat bands: chain-induced flat bands at the eigenenergies of the inserted chains, symmetry-protected zero-energy flat bands in bipartite edge-inflated lattices, and nearly flat junction bands near the spectral edges for sufficiently long chains. We analyze these mechanisms for ordered Lieb-$L$, super$^{L}$honeycomb, and super$^{L}$triangular lattices, and examine their response to bond disorder, site disorder, random magnetic flux, and randomness in the inflation process itself. While bond and site disorder broaden most flat bands, the zero-energy chiral band and the junction-induced flat bands remain robust under certain perturbations. Remarkably, substantial flat-band features also persist in randomly edge-inflated graphs, even in the absence of translational symmetry. In particular, the number of zero-energy states is found to be well estimated by the matching deficiency $N-2\nu(G)$, indicating that local tree-like structure continues to control the low-energy nullity. These results identify edge-inflated lattices as a broad class of systems in which geometry alone generates robust localization in both ordered and random settings.