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Ultrafast synchrotron X-ray imaging and multiphysics modelling of liquid phase fatigue exfoliation of graphite under ultrasound

Ultrafast synchrotron X-ray imaging and multiphysics modelling of liquid phase fatigue exfoliation of graphite under ultrasound

Qin, Ling, Maciejewska, Barbara M., Subroto, Tungky, Morton, Justin A., Porfyrakis, Kyriakos ORCID logoORCID: https://orcid.org/0000-0003-1364-0261, Tzanakis, Iakovos, Eskin, Dmitry G., Grobert, Nicole, Fezzaa, Kamel and Mi, Jiawei (2021) Ultrafast synchrotron X-ray imaging and multiphysics modelling of liquid phase fatigue exfoliation of graphite under ultrasound. Carbon, 186. pp. 227-237. ISSN 0008-6223 (doi:10.1016/j.carbon.2021.10.014)

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Abstract

Ultrasound-assisted liquid phase exfoliation is a promising method for manufacturing of 2D materials in large scale and sustainable manner. A large number of studies using ex-situ nano/micro structural characterization techniques have been made to investigate the underlying mechanisms, aiming to understand the exfoliation dynamics. Due to the complex multiphysics and multi-length nature of the process, those ex-situ methods cannot provide the real-time and in-situ dynamic information for understanding how exactly layer exfoliation starts and grows under ultrasound. Here, we used the ultrafast synchrotron-X-ray phase-contrast imaging (a combined temporal resolution of 3.68 ms and a spatial resolution of 1.9 mm/pixel) to study the exfoliation dynamics in real time and operando condition. We revealed, for the first time, the fatigue exfoliation phenomenon at the graphite surface caused by the imploding ultrasonic bubbles occurring cyclically in line with the ultrasound frequency. A multiphysics numerical model was also developed to calculate the shock wave produced at bubble implosion and the resulting cyclic and impulsive tensile and shear stresses acting on the graphite surface. Our research reveals that the graphite layer exfoliation rate and efficiency are predominantly determined by the number of imploding bubbles inside the effective cavitation bubble zone. The findings are valuable for developing industrial upscaling strategies for ultrasound processing of 2D materials.

Received 19 August 2021, Revised 1 October 2021, Accepted 4 October 2021, Available online 7 October 2021, Version of Record 14 October 2021.

Item Type: Article
Uncontrolled Keywords: ultrafast; synchrotron; X-ray; phase-contrast; imaging; 2D layered graphite materials; multi-physics modelling; liquid-phase exfoliation; ultrasound; exfoliation dynamics
Subjects: Q Science > QC Physics
T Technology > TP Chemical technology
Faculty / School / Research Centre / Research Group: Faculty of Engineering & Science
Faculty of Engineering & Science > School of Engineering (ENG)
Last Modified: 06 Jun 2022 15:18
URI: http://gala.gre.ac.uk/id/eprint/34224

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