English

Quantum spin Hall phase in multilayer graphene

Mesoscale and Nanoscale Physics 2015-07-08 v1

Abstract

The so called quantum spin Hall phase is a topologically non trivial insulating phase that is predicted to appear in graphene and graphene-like systems. In this work we address the question of whether this topological property persists in multilayered systems. We consider two situations: purely multilayer graphene and heterostructures where graphene is encapsulated by trivial insulators with a strong spin-orbit coupling. We use a four orbital tight-binding model that includes the full atomic spin-orbit coupling and we calculate the Z2Z_{2} topological invariant of the bulk states as well as the edge states of semi-infinite crystals with armchair termination. For homogeneous multilayers we find that even when the spin-orbit interaction opens a gap for all the possible stackings, only those with odd number of layers host gapless edge states while those with even number of layers are trivial insulators. For the heterostructures where graphene is encapsulated by trivial insulators, it turns out that the interlayer coupling is able to induce a topological gap whose size is controlled by the spin-orbit coupling of the encapsulating materials, indicating that the quantum spin Hall phase can be induced by proximity to trivial insulators.

Keywords

Cite

@article{arxiv.1503.06736,
  title  = {Quantum spin Hall phase in multilayer graphene},
  author = {N. A. Garcia-Martinez and J. L. Lado and J. Fernandez-Rossier},
  journal= {arXiv preprint arXiv:1503.06736},
  year   = {2015}
}

Comments

7 pages, 6 figures

R2 v1 2026-06-22T08:59:49.146Z