English

Fractonic Fractional Quantum Hall Effect

Strongly Correlated Electrons 2025-09-04 v4 Mesoscale and Nanoscale Physics

Abstract

In non-interacting systems, disorder can drive a trivial phase into a topological one. However little is known how to construct a fractional quantum Hall ground-state, a paradigmatic topologically ordered state, that exists both in crystalline and disordered lattices and is qualitatively different to known topological phases. Here, we propose a general method for building such a phase. This is done by coupling quantum wires placed aperiodically in real-space, where the spatial positioning allows us to tune the inter-wire couplings. We call the emergent phase the Fractonic Fractional Quantum Hall Effect as it displays a rich interplay of fractional quantum Hall physics with fractonic constraints, formed by coupling differently-fractionalised wires into a globally gapped phase. The ground state has an exponential degeneracy in system size, a signature of the emergence of fractons. It displays a rich phenomenology of excitations, which can either behave like anyons confined to move in one dimension (lineons), multiples of which can then hop between two wires (s-lineons) or be free to travel across the system (C-anyons), depending on the multiplicity. Both the ground state degeneracy and mutual statistics are directly determined by the real-space positions of the wires, which can be disordered. Our method provides an analytically solvable pathway to non-crystalline fractional quantum Hall effects and fractonic theories in two-dimensions, examples of which were lacking.

Keywords

Cite

@article{arxiv.2504.18337,
  title  = {Fractonic Fractional Quantum Hall Effect},
  author = {Justin Schirmann and Peru d'Ornellas and Charles Stahl and Adolfo G. Grushin},
  journal= {arXiv preprint arXiv:2504.18337},
  year   = {2025}
}

Comments

24 pages, 9 figures

R2 v1 2026-06-28T23:11:18.120Z