English

Disentangling modular Walker-Wang models via fermionic invertible boundaries

Strongly Correlated Electrons 2023-03-14 v3 Quantum Algebra Quantum Physics

Abstract

Walker-Wang models are fixed-point models of topological order in 3+13+1 dimensions constructed from a braided fusion category. For a modular input category M\mathcal M, the model itself is invertible and is believed to be in a trivial topological phase, whereas its standard boundary is supposed to represent a 2+12+1-dimensional chiral phase. In this work we explicitly show triviality of the model by constructing an invertible domain wall to vacuum as well as a disentangling generalized local unitary circuit in the case where M\mathcal M is a Drinfeld center. Moreover, we show that if we allow for fermionic (auxiliary) degrees of freedom inside the disentangling domain wall or circuit, the model becomes trivial for a larger class of modular fusion categories, namely those in the Witt classes generated by the Ising UMTC. In the appendices, we also discuss general (non-invertible) boundaries of general Walker-Wang models and describe a simple axiomatization of extended TQFT in terms of tensors.

Keywords

Cite

@article{arxiv.2208.03397,
  title  = {Disentangling modular Walker-Wang models via fermionic invertible boundaries},
  author = {Andreas Bauer},
  journal= {arXiv preprint arXiv:2208.03397},
  year   = {2023}
}

Comments

v3: Version published in PRB

R2 v1 2026-06-25T01:31:44.604Z