English

The bulk-edge correspondence for continuous dislocated systems

Analysis of PDEs 2019-01-30 v2

Abstract

We study topological aspects of defect modes for a family of operators {P(t)}t[0,2π]\{\mathscr{P}(t)\}_{t \in [0,2\pi]} on L2(R)L^2(\mathbb{R}). P(t)\mathscr{P}(t) is a periodic Schr\"odinger operator P0P_0 perturbed by a dislocated potential. This potential is periodic on the left and on the right, but acquires a phase defect tt from -\infty relative to ++\infty. When t=πt=\pi and the dislocation is small and adiabatic, Fefferman, Lee-Thorp and Weinstein showed in previous work that Dirac points of P0P_0 (degeneracies in the band spectrum of P0P_0) bifurcate to defect modes of P(π)\mathscr{P}(\pi). We show that these modes are topologically protected at the level of the family {P(t)}t[0,2π]\{\mathscr{P}(t)\}_{t \in [0,2\pi]}. This means that local perturbations cannot remove these states for all values of tt, even outside the small adiabatic regime studied by Fefferman-Lee-Thorp-Weinstein. We define two topological quantities: an edge index (the signed number of eigenvalues crossing an energy gap as tt runs from 00 to 2π2\pi) and a bulk index (the Chern number of a Bloch eigenbundle for the periodic operator near ++\infty). We prove that these indexes are equal to the same odd winding number. This shows the bulk-edge correspondence for the family {P(t)}t[0,2π]\{\mathscr{P}(t)\}_{t \in [0,2\pi]}. We express this winding number in terms of the asymptotic shape of the dislocation and of the Dirac point Bloch modes. We illustrate the topological depth of our model via the computation of the bulk/edge index on a few examples.

Cite

@article{arxiv.1810.10603,
  title  = {The bulk-edge correspondence for continuous dislocated systems},
  author = {Alexis Drouot},
  journal= {arXiv preprint arXiv:1810.10603},
  year   = {2019}
}

Comments

67 pages

R2 v1 2026-06-23T04:51:51.097Z