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.

Quantitative secondary electron imaging for work function extraction at atomic level and layer identification of graphene / Zhou, Y.; Fox, D. S.; Maguire, P.; O'Connell, R.; Masters, R.; Rodenburg, C.; Wu, H.; Dapor, M.; Chen, Y.; Zhang, H.. - In: SCIENTIFIC REPORTS. - ISSN 2045-2322. - 6:1(2016), p. 21045. [10.1038/srep21045]

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

Wu H.;Dapor M.;
2016-01-01

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.
2016
1
Zhou, Y.; Fox, D. S.; Maguire, P.; O'Connell, R.; Masters, R.; Rodenburg, C.; Wu, H.; Dapor, M.; Chen, Y.; Zhang, H.
Quantitative secondary electron imaging for work function extraction at atomic level and layer identification of graphene / Zhou, Y.; Fox, D. S.; Maguire, P.; O'Connell, R.; Masters, R.; Rodenburg, C.; Wu, H.; Dapor, M.; Chen, Y.; Zhang, H.. - In: SCIENTIFIC REPORTS. - ISSN 2045-2322. - 6:1(2016), p. 21045. [10.1038/srep21045]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11572/325754
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