Universal deformation pathways and flexural hardening of nanoscale 2D-material standing folds

Citation:

H. Chacham, A. P. M. Barboza, A. B. de Oliveira, C. K. de Oliveira, R. J. C. Batista, and B. R. A. Neves, “Universal deformation pathways and flexural hardening of nanoscale 2D-material standing folds,” Nanotechnology, vol. 29, no. 9, pp. 095704, 2018.

Abstract:

In the present work, we use atomic force microscopy nanomanipulation of 2D-material standing folds to investigate their mechanical deformation. Using graphene, h-BN and talc nanoscale wrinkles as testbeds, universal force–strain pathways are clearly uncovered and well-accounted for by an analytical model. Such universality further enables the investigation of each fold bending stiffness κ as a function of its characteristic height h 0 . We observe a more than tenfold increase of κ as h 0 increases in the 10–100 nm range, with power-law behaviors of κ versus h 0 with exponents larger than unity for the three materials. This implies anomalous scaling of the mechanical responses of nano-objects made from these materials.

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Last updated on 03/08/2018