Logo of Science Foundation Ireland  Logo of the Higher Education Authority, Ireland7 CapacitiesGPGPU Research Projects
Ireland's High-Performance Computing Centre | ICHEC
Home | News | Infrastructure | Outreach | Services | Research | Support | Education & Training | Consultancy | About Us | Login

Publication

Title:Quantification of Ink Diffusion in Microcontact Printing with Self-Assembled Monolayers
Authors:Gannon G., Larsson J.A., Greer J.C. and Thompson D., 2009
Abstract: Spreading of ink outside the desired printed area is one of the major limitations of microcontact printing (μ-CP) with alkanethiol self-assembled monolayers (SAMs) on gold. We use molecular dynamics (MD) computer simulations to quantify the temperature and concentration dependence of hexadecanethiol (HDT) ink spreading on HDT SAMs, modeling 18 distinct printing conditions using periodic simulation cells of ∼7 nm edge length and printing conditions ranging from 7 ink molecules per cell at 270 K to 42 ink molecules per cell at 371K. The computed alkanethiol ink diffusion rates on the SAM are of the same order of magnitude as bulk liquid alkanethiol diffusion rates at all but the lowest ink concentrations and highest temperatures, with up to 20−30 times increases in diffusion rates at the lowest concentration−highest temperature conditions. We show that although alkanethiol surfaces are autophobic, autophobicity is not enough to pin the ink solutions on the SAM, and so any overinking of the SAM will lead to spreading of the printed pattern. Comparison of experimental and calculated diffusion data supports an interpretation of pattern broadening as a mixture of spreading on fully and partially formed SAMs, and the calculated spreading rates establish some of the fundamental limitations of μ-CP in terms of stamp contact time and desired pattern width.
ICHEC Project:Computer simulations of nanopatterning systems
Publication:Langmuir (2009) 25: 242-247
URL: http://dx.doi.org/10.1021/la802548u
Status: Published

return to publications list