J D Fowlkes et al 2005 Nanotechnology 16 3101-3109 doi:10.1088/0957-4484/16/12/063
Abstract. The ability to control the permeability of a synthetic membrane structure formed by a spatially stochastic forest of vertically aligned carbon nanofibres is demonstrated. Control of membrane pore size and morphology was achieved by varying the thickness of a uniform, conformal coating of SiO2 on the nanofibre surfaces. Characterization of passive diffusion using fluorescence microscopy and labelled latex beads confirms the ability to alter membrane permeability. Further, statistically reproducible transport regimes are predicted for the spatially stochastic membrane as a function of the nanofibre diameter by a Monte Carlo simulation technique. Realizing predictable nanoscale behaviour in a microscopically random, statistical structure is essential for applications requiring controlled, species specific transport.
Print publication:
Issue 12 (December 2005)
Received 24 June 2005, in
final form 30 September 2005
Published 11 November 2005
Biological Nanoscale Systems group
Molecular Scale Engineering and Nanoscale Technologies group