English

Algebraic localization implies exponential localization in non-periodic insulators

Mathematical Physics 2022-02-03 v3 Mesoscale and Nanoscale Physics math.MP

Abstract

Exponentially-localized Wannier functions are a basis of the Fermi projection of a Hamiltonian consisting of functions which decay exponentially fast in space. In two and three spatial dimensions, it is well understood for periodic insulators that exponentially-localized Wannier functions exist if and only if there exists an orthonormal basis for the Fermi projection with finite second moment (i.e. all basis elements satisfy x2w(x)2dx<\int |\boldsymbol{x}|^2 |w(\boldsymbol{x})|^2 \,\text{d}{\boldsymbol{x}} < \infty). In this work, we establish a similar result for non-periodic insulators in two spatial dimensions. In particular, we prove that if there exists an orthonormal basis for the Fermi projection which satisfies x5+ϵw(x)2dx<\int |\boldsymbol{x}|^{5 + \epsilon} |w(\boldsymbol{x})|^2 \,\text{d}{\boldsymbol{x}} < \infty for some ϵ>0\epsilon > 0 then there also exists an orthonormal basis for the Fermi projection which decays exponentially fast in space. This result lends support to the Localization Dichotomy Conjecture for non-periodic systems recently proposed by Marcelli, Monaco, Moscolari, and Panati

Keywords

Cite

@article{arxiv.2101.02626,
  title  = {Algebraic localization implies exponential localization in non-periodic insulators},
  author = {Jianfeng Lu and Kevin D. Stubbs},
  journal= {arXiv preprint arXiv:2101.02626},
  year   = {2022}
}

Comments

32 pages. Simplified and streamlined proofs using updated results from arxiv:2003.06676v5

R2 v1 2026-06-23T21:53:15.191Z