Graphene membranes are adhered to substrates with patterned microcavities of prescribed volumes. By controlling the gas pressure within the microcavity, the membrane can be made to bulge and delaminate in a stable manner from the substrate. We study the analytical mechanics of this system, which is combined with experimental measurement to determine the elasticity of graphene and the adhesion energy between a substrate and a graphene (or other two-dimensional solid) membrane. A different microcavity configuration with a post in the center was also used, to study the pull-in behavior of graphene, which allows the determination of interfacial forces between two-dimensional nanomaterials and substrates.Â
References:
X. Liu, N.G. Boddeti, M.R. Szpunar, L. Wang, M.A. Rodriguez, R. Long,ÌýJ. Xiao, M.L. Dunn, and J.S. Bunch, ,ÌýNano LettersÌý(²¹³¦³¦±ð±è³Ù±ð»å)
N. G. Boddeti, S. P. Koenig, R. Long, J. Xiao, J. S. Bunch, and M. L. Dunn, , Journal of Applied Mechanics-Transactions of the ASME (accepted)