In situ room temperature electron-beam driven graphene growth from hydrocarbon contamination in a transmission electron microscope

Mark H. Rummeli; Yumo Pan; Liang Zhao; Jing Gao; Huy Q. Ta; Ignacio G. Martinez; Rafael G. Mendes; Thomas Gemming; Lei Fu; Alicja Bachmatiuk; Zhongfan Liu

doi:10.3390/ma11060896

In situ room temperature electron-beam driven graphene growth from hydrocarbon contamination in a transmission electron microscope

Mark H. Rummeli^*, Yumo Pan, Liang Zhao, Jing Gao, Huy Q. Ta, Ignacio G. Martinez, Rafael G. Mendes, Thomas Gemming, Lei Fu, Alicja Bachmatiuk, Zhongfan Liu

^*Corresponding author for this work

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

Abstract

The excitement of graphene (as well as 2D materials in general) has generated numerous procedures for the fabrication of graphene. Here we present a mini-review on a rather less known, but attractive, in situ means to fabricate graphene inside a transmission electron microscope (TEM). This is achieved in a conventional TEM (viz. no sophisticated specimen holders or microscopes are required) and takes advantage of inherent hydrocarbon contamination as a carbon source. Both catalyst free and single atom catalyst approaches are reviewed. An advantage of this technique is that not only can the growth process be imaged in situ, but this can also be achieved with atomic resolution. Moreover, in the future, one can anticipate such approaches enabling the growth of nano-materials with atomic precision.

Original language	English
Article number	896
Journal	Materials
Volume	11
Issue number	6
DOIs	https://doi.org/10.3390/ma11060896
Publication status	Published - Jun 2018

Keywords

Graphene
In situ TEM
Synthesis

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title = "In situ room temperature electron-beam driven graphene growth from hydrocarbon contamination in a transmission electron microscope",

abstract = "The excitement of graphene (as well as 2D materials in general) has generated numerous procedures for the fabrication of graphene. Here we present a mini-review on a rather less known, but attractive, in situ means to fabricate graphene inside a transmission electron microscope (TEM). This is achieved in a conventional TEM (viz. no sophisticated specimen holders or microscopes are required) and takes advantage of inherent hydrocarbon contamination as a carbon source. Both catalyst free and single atom catalyst approaches are reviewed. An advantage of this technique is that not only can the growth process be imaged in situ, but this can also be achieved with atomic resolution. Moreover, in the future, one can anticipate such approaches enabling the growth of nano-materials with atomic precision.",

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AU - Rummeli, Mark H.

AU - Pan, Yumo

AU - Zhao, Liang

AU - Gao, Jing

AU - Ta, Huy Q.

AU - Martinez, Ignacio G.

AU - Mendes, Rafael G.

AU - Gemming, Thomas

AU - Fu, Lei

AU - Bachmatiuk, Alicja

AU - Liu, Zhongfan

PY - 2018/6

Y1 - 2018/6

N2 - The excitement of graphene (as well as 2D materials in general) has generated numerous procedures for the fabrication of graphene. Here we present a mini-review on a rather less known, but attractive, in situ means to fabricate graphene inside a transmission electron microscope (TEM). This is achieved in a conventional TEM (viz. no sophisticated specimen holders or microscopes are required) and takes advantage of inherent hydrocarbon contamination as a carbon source. Both catalyst free and single atom catalyst approaches are reviewed. An advantage of this technique is that not only can the growth process be imaged in situ, but this can also be achieved with atomic resolution. Moreover, in the future, one can anticipate such approaches enabling the growth of nano-materials with atomic precision.

AB - The excitement of graphene (as well as 2D materials in general) has generated numerous procedures for the fabrication of graphene. Here we present a mini-review on a rather less known, but attractive, in situ means to fabricate graphene inside a transmission electron microscope (TEM). This is achieved in a conventional TEM (viz. no sophisticated specimen holders or microscopes are required) and takes advantage of inherent hydrocarbon contamination as a carbon source. Both catalyst free and single atom catalyst approaches are reviewed. An advantage of this technique is that not only can the growth process be imaged in situ, but this can also be achieved with atomic resolution. Moreover, in the future, one can anticipate such approaches enabling the growth of nano-materials with atomic precision.

KW - Graphene

KW - In situ TEM

KW - Synthesis

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DO - 10.3390/ma11060896

M3 - Article

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VL - 11

JO - Materials

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ER -

In situ room temperature electron-beam driven graphene growth from hydrocarbon contamination in a transmission electron microscope

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