English

Quantum doubles in symmetric blockade structures

Quantum Physics 2025-11-07 v1 Quantum Gases Atomic Physics

Abstract

Exactly solvable models of topologically ordered phases with non-abelian anyons typically require complicated many-body interactions which do not naturally appear in nature. This motivates the "inverse problem" of quantum many-body physics: given microscopic systems with experimentally realistic two-body interactions, how to design a Hamiltonian that realizes a desired topological phase? Here we solve this problem on a platform motivated by Rydberg atoms, where elementary two-level systems couple via simple blockade interactions. Within this framework, we construct Hamiltonians that realize topological orders described by non-abelian quantum double models. We analytically prove the existence of topological order in the ground state, and present efficient schemes to prepare these states. We also introduce protocols for the controlled adiabatic braiding of anyonic excitations to probe their non-abelian statistics. Our construction is generic and applies to quantum doubles D(G)\mathcal{D}(G) for arbitrary finite groups GG. We illustrate braiding for the simplest non-abelian quantum double D(S3)\mathcal{D}(S_3).

Keywords

Cite

@article{arxiv.2511.04414,
  title  = {Quantum doubles in symmetric blockade structures},
  author = {Hans Peter Büchler and Tobias F. Maier and Simon Fell and Nicolai Lang},
  journal= {arXiv preprint arXiv:2511.04414},
  year   = {2025}
}

Comments

39 pages, 12 figures

R2 v1 2026-07-01T07:24:38.649Z