Jayeeta Ghosh, Masaomi Hatakeyama, Petra Träskelin, Chenyue Xing, and Roland Faller

pp. 167 - 173

Abstract

The computational study of soft materials under confinement for bio- and nanotechnology still poses significant challenges but has come a long way in the last decade. It is possible to realistically model and understand the fundamental mechanisms which are at play if soft materials are confined to nanometer dimensions. Here, we present several recent
examples of such studies. Thin polymer films are abundantly used as friction modifiers or steric stabilizers. We show how systematic modeling can shed light on the interplay between entropic and energetic interactions. Thin glassy films are critical for the success of nanolithography. For that we have to understand the effect of confinement on the glass transition behavior in order to guarantee the stability and integrity of the lithographic masks. Simulations aim to understand the
fundamental differences in the densities of states of glass formers in bulk and under confinement. With the advent of bionanotechnology the structure and phase behavior of lipid membranes as models for cellular membranes at the nano scale length is of importance due to implications in understanding the role of the lipids in biochemical membrane processes.