Fractal hierarchy enables exponential scaling of topological boundary states

TL;DR

This paper introduces fractal-inspired lattices that enable exponential scaling of topological boundary states, combining self-similar hierarchy with periodic order to control boundary-state multiplicity.

Contribution

The work demonstrates exponential growth of topological boundary states in fractal-inspired lattices, confirmed experimentally, revealing a new materials design principle.

Findings

Number of boundary states grows exponentially with fractal generation.

Boundary states are an integer multiple of minigaps, determined by symmetry.

Experimental confirmation in laser-written photonic lattices.

Abstract

Exponential growth describes an extremely rapid process ubiquitous across mathematics and diverse physical, biological, and technological systems. Here, we introduce a class of fractal-inspired lattices that combine long-range periodic order with self-similar hierarchy, establishing a structural motif that enables exponential scaling of topological boundary states. We demonstrate this phenomenon in (i) a quasi-one-dimensional lattice chain constructed from Koch-curve unit cells and (ii) a two-dimensional periodic tiling lattice composed of Sierpinski-gasket unit cells. We show that, for suitable coupling parameters, both the number of topological boundary states $N_{\ell}$ and the number of topological minigaps $M_{\ell}$ grow exponentially with the fractal generation index $\ell$. We find that $N_{\ell}$ is an integer multiple of $M_{\ell}$, with the integer determined by the underlying symmetry. This hierarchical scaling law is captured by multi-topological-phase theory and confirmed experimentally in laser-written photonic lattices. Our results identify fractal hierarchy as a materials architecture principle for controlling boundary-state multiplicity, revealing an interplay between topology, self-similar geometry, and periodic order. More broadly, this work suggests a route to synthetic materials and integrated photonic platforms in which large numbers of robust boundary modes can be engineered within compact architectures.