Stacking transition in rhombohedral graphite

Tataiana  Latychevskaia; Seok-Kyun Son; Yaping Yang; Dale Chancellor; Michael Brown; Servet Ozdemir; Ivan Madan; Gabriele Berruto; Artem Mishchenko; Konstantin Novoselov

doi:10.1007/s11467-018-0867-y

Stacking transition in rhombohedral graphite

Tataiana Latychevskaia, Seok-Kyun Son, Yaping Yang, Dale Chancellor, Michael Brown, Servet Ozdemir, Ivan Madan, Gabriele Berruto, Artem Mishchenko, Konstantin Novoselov

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

Abstract

Few-layer graphene (FLG) has recently been intensively investigated for its variable electronic properties, which are defined by a local atomic arrangement. While the most natural arrangement of layers in FLG is ABA (Bernal) stacking, a metastable ABC (rhombohedral) stacking, characterized by a relatively high-energy barrier, can also occur. When both types of stacking occur in one FLG device, the arrangement results in an in-plane heterostructure with a domain wall (DW). In this paper, we present two approaches to demonstrate that the ABC stacking in FLG can be controllably and locally turned into the ABA stacking. In the first approach, we introduced Joule heating, and the transition was characterized by 2D peak Raman spectra at a submicron spatial resolution. The transition was initiated in a small region, and then the DW was controllably shifted until the entire device became ABA stacked. In the second approach, the transition was achieved by illuminating the ABC region with a train of 790-nm-wavelength laser pulses, and the transition was visualized by transmission electron microscopy in both diffraction and dark-field imaging modes. Further, using this approach, the DW was visualized at a nanoscale spatial resolution in the dark-field imaging mode

Original language	English
Journal	Frontiers of Physics
Volume	14
Issue number	1
Early online date	24 Oct 2018
DOIs	https://doi.org/10.1007/s11467-018-0867-y
Publication status	Published - Feb 2019

Keywords

Rhombohedral
Graphite

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10.1007/s11467-018-0867-y

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title = "Stacking transition in rhombohedral graphite",

abstract = "Few-layer graphene (FLG) has recently been intensively investigated for its variable electronic properties, which are defined by a local atomic arrangement. While the most natural arrangement of layers in FLG is ABA (Bernal) stacking, a metastable ABC (rhombohedral) stacking, characterized by a relatively high-energy barrier, can also occur. When both types of stacking occur in one FLG device, the arrangement results in an in-plane heterostructure with a domain wall (DW). In this paper, we present two approaches to demonstrate that the ABC stacking in FLG can be controllably and locally turned into the ABA stacking. In the first approach, we introduced Joule heating, and the transition was characterized by 2D peak Raman spectra at a submicron spatial resolution. The transition was initiated in a small region, and then the DW was controllably shifted until the entire device became ABA stacked. In the second approach, the transition was achieved by illuminating the ABC region with a train of 790-nm-wavelength laser pulses, and the transition was visualized by transmission electron microscopy in both diffraction and dark-field imaging modes. Further, using this approach, the DW was visualized at a nanoscale spatial resolution in the dark-field imaging mode",

keywords = "Rhombohedral, Graphite",

author = "Tataiana Latychevskaia and Seok-Kyun Son and Yaping Yang and Dale Chancellor and Michael Brown and Servet Ozdemir and Ivan Madan and Gabriele Berruto and Artem Mishchenko and Konstantin Novoselov",

year = "2019",

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doi = "10.1007/s11467-018-0867-y",

language = "English",

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journal = "Frontiers of Physics",

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AU - Latychevskaia, Tataiana

AU - Son, Seok-Kyun

AU - Yang, Yaping

AU - Chancellor, Dale

AU - Brown, Michael

AU - Ozdemir, Servet

AU - Madan, Ivan

AU - Berruto, Gabriele

AU - Mishchenko, Artem

AU - Novoselov, Konstantin

PY - 2019/2

Y1 - 2019/2

N2 - Few-layer graphene (FLG) has recently been intensively investigated for its variable electronic properties, which are defined by a local atomic arrangement. While the most natural arrangement of layers in FLG is ABA (Bernal) stacking, a metastable ABC (rhombohedral) stacking, characterized by a relatively high-energy barrier, can also occur. When both types of stacking occur in one FLG device, the arrangement results in an in-plane heterostructure with a domain wall (DW). In this paper, we present two approaches to demonstrate that the ABC stacking in FLG can be controllably and locally turned into the ABA stacking. In the first approach, we introduced Joule heating, and the transition was characterized by 2D peak Raman spectra at a submicron spatial resolution. The transition was initiated in a small region, and then the DW was controllably shifted until the entire device became ABA stacked. In the second approach, the transition was achieved by illuminating the ABC region with a train of 790-nm-wavelength laser pulses, and the transition was visualized by transmission electron microscopy in both diffraction and dark-field imaging modes. Further, using this approach, the DW was visualized at a nanoscale spatial resolution in the dark-field imaging mode

AB - Few-layer graphene (FLG) has recently been intensively investigated for its variable electronic properties, which are defined by a local atomic arrangement. While the most natural arrangement of layers in FLG is ABA (Bernal) stacking, a metastable ABC (rhombohedral) stacking, characterized by a relatively high-energy barrier, can also occur. When both types of stacking occur in one FLG device, the arrangement results in an in-plane heterostructure with a domain wall (DW). In this paper, we present two approaches to demonstrate that the ABC stacking in FLG can be controllably and locally turned into the ABA stacking. In the first approach, we introduced Joule heating, and the transition was characterized by 2D peak Raman spectra at a submicron spatial resolution. The transition was initiated in a small region, and then the DW was controllably shifted until the entire device became ABA stacked. In the second approach, the transition was achieved by illuminating the ABC region with a train of 790-nm-wavelength laser pulses, and the transition was visualized by transmission electron microscopy in both diffraction and dark-field imaging modes. Further, using this approach, the DW was visualized at a nanoscale spatial resolution in the dark-field imaging mode

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KW - Graphite

U2 - 10.1007/s11467-018-0867-y

DO - 10.1007/s11467-018-0867-y

M3 - Article

SN - 2095-0462

VL - 14

JO - Frontiers of Physics

JF - Frontiers of Physics

IS - 1

ER -

Stacking transition in rhombohedral graphite

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