2016
DOI: 10.1088/2053-1583/3/1/014008
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Bifurcations of edge states—topologically protected and non-protected—in continuous 2D honeycomb structures

Abstract: Abstract. Edge states are time-harmonic solutions to energy-conserving wave equations, which are propagating parallel to a line-defect or "edge" and are localized transverse to it. This paper summarizes and extends the authors' work on the bifurcation of topologically protected edge states in continuous twodimensional honeycomb structures.We consider a family of Schrödinger Hamiltonians consisting of a bulk honeycomb potential and a perturbing edge potential. The edge potential interpolates between two differe… Show more

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Cited by 27 publications
(41 citation statements)
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“…For large, a consequence of Theorem 6.1 and the results in [18] is the existence of spectral gaps about Dirac points (see Section 7) of C 2 V when the Hamiltonian is perturbed in such a way as to break PT symmetry. In [16] (see also [15]), we develop a theory of protected edge states for honeycomb structures, perturbed by a class of line defects (domain walls) in the direction of an element of ƒ h (rational edges). (B) Corollary 6.4: Protected edge states in honeycomb structures with line defects.…”
Section: Summary Of Resultsmentioning
confidence: 99%
“…For large, a consequence of Theorem 6.1 and the results in [18] is the existence of spectral gaps about Dirac points (see Section 7) of C 2 V when the Hamiltonian is perturbed in such a way as to break PT symmetry. In [16] (see also [15]), we develop a theory of protected edge states for honeycomb structures, perturbed by a class of line defects (domain walls) in the direction of an element of ƒ h (rational edges). (B) Corollary 6.4: Protected edge states in honeycomb structures with line defects.…”
Section: Summary Of Resultsmentioning
confidence: 99%
“…For k ∈ B h , let ( E ε (k), ε (x; k)) denote the eigenpair associated with a lowest spectral band. In [8], we calculate that the edge state bifurcation is seeded by a discrete eigenvalue effective Schrödinger operator: 12) and…”
Section: Non-topologically Protected Bifurcations Of Edge Statesmentioning
confidence: 99%
“…If κ(ζ ) is chosen as above, then Q eff (ζ ; (1 − θ)κ + θκ ), 0 ≤ θ ≤ 1, provides a smooth homotopy from a Schrödinger Hamiltonian for which there is a bifurcation of edge states (H (ε,δ) with domain wall κ) to one for which the branch of edge states does not exist (H (ε,δ) with domain wall κ ). Therefore, this type of bifurcation is not topologically protected; see [8] for a more detailed discussion. This contrast between topologically protected states and non-protected states is explained and explored numerically, in a one-dimensional setting in [25].…”
Section: Non-topologically Protected Bifurcations Of Edge Statesmentioning
confidence: 99%
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“…13 For 2D Schrödinger operators with honeycombsymmetric potentials, existence and stability of Dirac cones was established, explained, and studied [26,[132][133][134][135][136]186]. The Schrödinger operator with honeycomb lattice of point scatterers was considered in [263].…”
Section: On a Z 2 -Periodic Graph γ Having Just Two Vertices (Atoms)mentioning
confidence: 99%