Liquid phase exfoliation is a commonly used method to produce 2D nanosheets from a range of layered crystals. However, such nanosheets display broad size and thickness distributions and correlations between area and thickness, issues that limit nanosheet application potential. To understand the factors controlling the exfoliation process, we have liquid-exfoliated 11 different layered materials, size-selecting each into fractions before using AFM to measure the nanosheet length, width, and thickness distributions for each fraction. The resultant data show a clear power-law scaling of nanosheet area with thickness for each material. We have developed a simple nonequilibrium thermodynamics-based model predicting that the power-law prefactor is proportional to both the ratios of in-plane-tearing/out-of-plane-peeling energies and in-plane/out-of-plane moduli. By comparing the experimental data with the modulus ratio calculated from first-principles, we find close agreement between experiment and theory. This supports our hypothesis that energy equipartition holds between nanosheet tearing and peeling during sonication-assisted exfoliation.

Backes, C., Campi, D., Szydlowska, B., Synnatschke, K., Ojala, E., Rashvand, F., et al. (2019). Equipartition of Energy Defines the Size-Thickness Relationship in Liquid-Exfoliated Nanosheets. ACS NANO, 13(6), 7050-7061 [10.1021/acsnano.9b02234].

Equipartition of Energy Defines the Size-Thickness Relationship in Liquid-Exfoliated Nanosheets

Campi D.;
2019

Abstract

Liquid phase exfoliation is a commonly used method to produce 2D nanosheets from a range of layered crystals. However, such nanosheets display broad size and thickness distributions and correlations between area and thickness, issues that limit nanosheet application potential. To understand the factors controlling the exfoliation process, we have liquid-exfoliated 11 different layered materials, size-selecting each into fractions before using AFM to measure the nanosheet length, width, and thickness distributions for each fraction. The resultant data show a clear power-law scaling of nanosheet area with thickness for each material. We have developed a simple nonequilibrium thermodynamics-based model predicting that the power-law prefactor is proportional to both the ratios of in-plane-tearing/out-of-plane-peeling energies and in-plane/out-of-plane moduli. By comparing the experimental data with the modulus ratio calculated from first-principles, we find close agreement between experiment and theory. This supports our hypothesis that energy equipartition holds between nanosheet tearing and peeling during sonication-assisted exfoliation.
Articolo in rivista - Articolo scientifico
2D; energetics; exfoliation; mechanics; modeling; size-selection;
English
2019
13
6
7050
7061
none
Backes, C., Campi, D., Szydlowska, B., Synnatschke, K., Ojala, E., Rashvand, F., et al. (2019). Equipartition of Energy Defines the Size-Thickness Relationship in Liquid-Exfoliated Nanosheets. ACS NANO, 13(6), 7050-7061 [10.1021/acsnano.9b02234].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/409815
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