Detachment of semiflexible polymer chains from a substrate - a Molecular Dynamics investigation

Abstract

Using Molecular Dynamics simulations, we study the force-induced detachment of a coarse-grained model polymer chain from an adhesive substrate. One of the chain ends is thereby pulled at constant speed off the attractive substrate and the resulting saw-tooth profile of the measured mean force < f > vs height D of the end-segment over the plane is analyzed for a broad variety of parameters. It is shown that the observed characteristic oscillations in the < f >-D profile depend on the bending and not on the torsional stiffness of the detached chains. Allowing for the presence of hydrodynamic interactions (HI) in a setup with explicit solvent and DPD-thermostat, rather than the case of Langevin thermostat, one finds that HI have little effect on the < f >-D profile. Also the change of substrate affinity with respect to the solvent from solvophilic to solvophobic is found to play negligible role in the desorption process. In contrast, a changing ratio εsA / εsB of the binding energies of A- and B-segments in the detachment of an AB-copolymer from adhesive surface strongly changes the < f >-D profile whereby the B-spikes vanish when εsA / εsB < 0.15. Eventually, performing an atomistic simulation of a (bio)-polymer polyglycine, we demonstrate that the simulation results, derived from our coarse-grained model, comply favorably with those from the all-atom simulation.