Defect bound states in the continuum of bilayer electronic materials without symmetry protection

Daniel Massatt; Stephen P. Shipman; Ilya Vekhter; Justin H. Wilson

doi:10.1103/PhysRevB.111.L060101

Defect bound states in the continuum of bilayer electronic materials without symmetry protection

Daniel Massatt
, Stephen P. Shipman
, Ilya Vekhter
, Justin H. Wilson

Research output: Contribution to journal › Article › peer-review

Abstract

We analyze a class of bound defect states in the continuum electronic spectrum of bilayer materials, which emerge independent of symmetry protection or additional degrees of freedom. Taking graphene as a prototypical example, our comparative analysis of AA- and AB-stacked bilayer graphene demonstrates that these states originate from the intrinsic algebraic structure of the tight-binding Hamiltonian when trigonal warping is neglected rather than any underlying symmetry. The inclusion of trigonal warping and higher-order hoppings broadens the bound states into long-lived resonances. This discovery provides a distinct pathway to defect and band-structure engineering. We conclude with a proposed protocol for observing these states in scanning tunneling microscopy experiments.

Original language	English (US)
Article number	L060101
Journal	Physical Review B
Volume	111
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevB.111.L060101
State	Published - Feb 1 2025
Externally published	Yes

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.111.L060101

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title = "Defect bound states in the continuum of bilayer electronic materials without symmetry protection",

abstract = "We analyze a class of bound defect states in the continuum electronic spectrum of bilayer materials, which emerge independent of symmetry protection or additional degrees of freedom. Taking graphene as a prototypical example, our comparative analysis of AA- and AB-stacked bilayer graphene demonstrates that these states originate from the intrinsic algebraic structure of the tight-binding Hamiltonian when trigonal warping is neglected rather than any underlying symmetry. The inclusion of trigonal warping and higher-order hoppings broadens the bound states into long-lived resonances. This discovery provides a distinct pathway to defect and band-structure engineering. We conclude with a proposed protocol for observing these states in scanning tunneling microscopy experiments.",

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doi = "10.1103/PhysRevB.111.L060101",

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AU - Shipman, Stephen P.

AU - Vekhter, Ilya

AU - Wilson, Justin H.

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Y1 - 2025/2/1

N2 - We analyze a class of bound defect states in the continuum electronic spectrum of bilayer materials, which emerge independent of symmetry protection or additional degrees of freedom. Taking graphene as a prototypical example, our comparative analysis of AA- and AB-stacked bilayer graphene demonstrates that these states originate from the intrinsic algebraic structure of the tight-binding Hamiltonian when trigonal warping is neglected rather than any underlying symmetry. The inclusion of trigonal warping and higher-order hoppings broadens the bound states into long-lived resonances. This discovery provides a distinct pathway to defect and band-structure engineering. We conclude with a proposed protocol for observing these states in scanning tunneling microscopy experiments.

AB - We analyze a class of bound defect states in the continuum electronic spectrum of bilayer materials, which emerge independent of symmetry protection or additional degrees of freedom. Taking graphene as a prototypical example, our comparative analysis of AA- and AB-stacked bilayer graphene demonstrates that these states originate from the intrinsic algebraic structure of the tight-binding Hamiltonian when trigonal warping is neglected rather than any underlying symmetry. The inclusion of trigonal warping and higher-order hoppings broadens the bound states into long-lived resonances. This discovery provides a distinct pathway to defect and band-structure engineering. We conclude with a proposed protocol for observing these states in scanning tunneling microscopy experiments.

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ER -

Defect bound states in the continuum of bilayer electronic materials without symmetry protection

Abstract

All Science Journal Classification (ASJC) codes

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