Universal Scherrer equation for graphene fragments

Lim, D.J.; Marks, Nigel; Rowles, Matthew

doi:10.1016/j.carbon.2020.02.064

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Access Status

Open access

Authors

Lim, D.J.

Marks, Nigel

Rowles, Matthew

Date

2020

Type

Journal Article

Metadata

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Citation

Lim, D.J. and Marks, N.A. and Rowles, M.R. 2020. Universal Scherrer equation for graphene fragments. Carbon. 162: pp. 475-480.

Source Title

Carbon

DOI

10.1016/j.carbon.2020.02.064

ISSN

0008-6223

Faculty

Faculty of Science and Engineering

School

School of Electrical Engineering, Computing and Mathematical Sciences (EECMS)

John de Laeter Centre (JdLC)

Abstract

Graphene fragments spanning a wide range of size and shape were studied computationally using the Debye scattering equation. The calculated diffraction patterns were analysed using the Scherrer equation to infer the fragment size, La. Comparison with the known fragment sizes reveals a strong affine relationship between La and the Scherrer quantity λ/(Bcosθ). To preserve this relationship, we propose modifying the Scherrer equation to include an empirical additive constant. Our approach solves the well-known problem of size-dependence in the shape factor and yields a universal expression by defining La as the square-root of the fragment area. The relationship between observed diffraction peak positions and unit cell parameters is also discussed.

Except where otherwise noted, this item's license is described as http://creativecommons.org/licenses/by-nc-nd/4.0/