Silicon-carbon bond inversions driven by 60-kev electrons in graphene

Toma Susi; Jani Kotakoski; Demie Kepaptsoglou; Clemens Mangler; Tracy C. Lovejoy; Ondrej L. Krivanek; Recep Zan; Ursel Bangert; Paola Ayala; Jannik C. Meyer; Quentin Ramasse

doi:10.1103/PhysRevLett.113.115501

Silicon-carbon bond inversions driven by 60-kev electrons in graphene

Toma Susi, Jani Kotakoski, Demie Kepaptsoglou, Clemens Mangler, Tracy C. Lovejoy, Ondrej L. Krivanek, Recep Zan, Ursel Bangert, Paola Ayala, Jannik C. Meyer, Quentin Ramasse

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

Abstract

We demonstrate that 60-keV electron irradiation drives the diffusion of threefold-coordinated Si dopants in graphene by one lattice site at a time. First principles simulations reveal that each step is caused by an electron impact on a C atom next to the dopant. Although the atomic motion happens below our experimental time resolution, stochastic analysis of 38 such lattice jumps reveals a probability for their occurrence in a good agreement with the simulations. Conversions from three- to fourfold coordinated dopant structures and the subsequent reverse process are significantly less likely than the direct bond inversion. Our results thus provide a model of nondestructive and atomically precise structural modification and detection for two-dimensional materials.

Original language	English
Article number	115501
Journal	Physical Review Letters
Volume	113
Issue number	11
DOIs	https://doi.org/10.1103/PhysRevLett.113.115501
Publication status	Published - 12 Sep 2014

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10.1103/PhysRevLett.113.115501

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title = "Silicon-carbon bond inversions driven by 60-kev electrons in graphene",

abstract = "We demonstrate that 60-keV electron irradiation drives the diffusion of threefold-coordinated Si dopants in graphene by one lattice site at a time. First principles simulations reveal that each step is caused by an electron impact on a C atom next to the dopant. Although the atomic motion happens below our experimental time resolution, stochastic analysis of 38 such lattice jumps reveals a probability for their occurrence in a good agreement with the simulations. Conversions from three- to fourfold coordinated dopant structures and the subsequent reverse process are significantly less likely than the direct bond inversion. Our results thus provide a model of nondestructive and atomically precise structural modification and detection for two-dimensional materials.",

author = "Toma Susi and Jani Kotakoski and Demie Kepaptsoglou and Clemens Mangler and Lovejoy, {Tracy C.} and Krivanek, {Ondrej L.} and Recep Zan and Ursel Bangert and Paola Ayala and Meyer, {Jannik C.} and Quentin Ramasse",

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year = "2014",

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day = "12",

doi = "10.1103/PhysRevLett.113.115501",

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T1 - Silicon-carbon bond inversions driven by 60-kev electrons in graphene

AU - Susi, Toma

AU - Kotakoski, Jani

AU - Kepaptsoglou, Demie

AU - Mangler, Clemens

AU - Lovejoy, Tracy C.

AU - Krivanek, Ondrej L.

AU - Zan, Recep

AU - Bangert, Ursel

AU - Ayala, Paola

AU - Meyer, Jannik C.

AU - Ramasse, Quentin

PY - 2014/9/12

Y1 - 2014/9/12

N2 - We demonstrate that 60-keV electron irradiation drives the diffusion of threefold-coordinated Si dopants in graphene by one lattice site at a time. First principles simulations reveal that each step is caused by an electron impact on a C atom next to the dopant. Although the atomic motion happens below our experimental time resolution, stochastic analysis of 38 such lattice jumps reveals a probability for their occurrence in a good agreement with the simulations. Conversions from three- to fourfold coordinated dopant structures and the subsequent reverse process are significantly less likely than the direct bond inversion. Our results thus provide a model of nondestructive and atomically precise structural modification and detection for two-dimensional materials.

AB - We demonstrate that 60-keV electron irradiation drives the diffusion of threefold-coordinated Si dopants in graphene by one lattice site at a time. First principles simulations reveal that each step is caused by an electron impact on a C atom next to the dopant. Although the atomic motion happens below our experimental time resolution, stochastic analysis of 38 such lattice jumps reveals a probability for their occurrence in a good agreement with the simulations. Conversions from three- to fourfold coordinated dopant structures and the subsequent reverse process are significantly less likely than the direct bond inversion. Our results thus provide a model of nondestructive and atomically precise structural modification and detection for two-dimensional materials.

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DO - 10.1103/PhysRevLett.113.115501

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VL - 113

JO - Physical Review Letters

JF - Physical Review Letters

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ER -

Silicon-carbon bond inversions driven by 60-kev electrons in graphene

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