Quantitative secondary electron imaging for work function extraction at atomic level and layer identification of graphene

Yangbo Zhou; Daniel S. Fox; Pierce Maguire; Robert O'Connell; Robert Masters; Cornelia Rodenburg; Hanchun Wu; Maurizio Dapor; Ying Chen; Hongzhou Zhang

doi:10.1038/srep21045

Quantitative secondary electron imaging for work function extraction at atomic level and layer identification of graphene

Yangbo Zhou
, Daniel S. Fox
, Pierce Maguire
, Robert O'Connell
, Robert Masters
, Cornelia Rodenburg
, Hanchun Wu
, Maurizio Dapor
, Ying Chen
, Hongzhou Zhang^*

^*Corresponding author for this work

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

37 Citations (Scopus)

Abstract

Two-dimensional (2D) materials usually have a layer-dependent work function, which require fast and accurate detection for the evaluation of their device performance. A detection technique with high throughput and high spatial resolution has not yet been explored. Using a scanning electron microscope, we have developed and implemented a quantitative analytical technique which allows effective extraction of the work function of graphene. This technique uses the secondary electron contrast and has nanometre-resolved layer information. The measurement of few-layer graphene flakes shows the variation of work function between graphene layers with a precision of less than 10 meV. It is expected that this technique will prove extremely useful for researchers in a broad range of fields due to its revolutionary throughput and accuracy.

Original language	English
Article number	21045
Journal	Scientific Reports
Volume	6
DOIs	https://doi.org/10.1038/srep21045
Publication status	Published - 16 Feb 2016
Externally published	Yes

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10.1038/srep21045

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title = "Quantitative secondary electron imaging for work function extraction at atomic level and layer identification of graphene",

abstract = "Two-dimensional (2D) materials usually have a layer-dependent work function, which require fast and accurate detection for the evaluation of their device performance. A detection technique with high throughput and high spatial resolution has not yet been explored. Using a scanning electron microscope, we have developed and implemented a quantitative analytical technique which allows effective extraction of the work function of graphene. This technique uses the secondary electron contrast and has nanometre-resolved layer information. The measurement of few-layer graphene flakes shows the variation of work function between graphene layers with a precision of less than 10 meV. It is expected that this technique will prove extremely useful for researchers in a broad range of fields due to its revolutionary throughput and accuracy.",

author = "Yangbo Zhou and Fox, \{Daniel S.\} and Pierce Maguire and Robert O'Connell and Robert Masters and Cornelia Rodenburg and Hanchun Wu and Maurizio Dapor and Ying Chen and Hongzhou Zhang",

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T1 - Quantitative secondary electron imaging for work function extraction at atomic level and layer identification of graphene

AU - Zhou, Yangbo

AU - Fox, Daniel S.

AU - Maguire, Pierce

AU - O'Connell, Robert

AU - Masters, Robert

AU - Rodenburg, Cornelia

AU - Wu, Hanchun

AU - Dapor, Maurizio

AU - Chen, Ying

AU - Zhang, Hongzhou

PY - 2016/2/16

Y1 - 2016/2/16

N2 - Two-dimensional (2D) materials usually have a layer-dependent work function, which require fast and accurate detection for the evaluation of their device performance. A detection technique with high throughput and high spatial resolution has not yet been explored. Using a scanning electron microscope, we have developed and implemented a quantitative analytical technique which allows effective extraction of the work function of graphene. This technique uses the secondary electron contrast and has nanometre-resolved layer information. The measurement of few-layer graphene flakes shows the variation of work function between graphene layers with a precision of less than 10 meV. It is expected that this technique will prove extremely useful for researchers in a broad range of fields due to its revolutionary throughput and accuracy.

AB - Two-dimensional (2D) materials usually have a layer-dependent work function, which require fast and accurate detection for the evaluation of their device performance. A detection technique with high throughput and high spatial resolution has not yet been explored. Using a scanning electron microscope, we have developed and implemented a quantitative analytical technique which allows effective extraction of the work function of graphene. This technique uses the secondary electron contrast and has nanometre-resolved layer information. The measurement of few-layer graphene flakes shows the variation of work function between graphene layers with a precision of less than 10 meV. It is expected that this technique will prove extremely useful for researchers in a broad range of fields due to its revolutionary throughput and accuracy.

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SN - 2045-2322

VL - 6

JO - Scientific Reports

JF - Scientific Reports

M1 - 21045

ER -

Quantitative secondary electron imaging for work function extraction at atomic level and layer identification of graphene

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