AFM-Based Single Molecule Force Spectroscopy of End-Grafted Poly(acrylic acid) Monolayers

Abstract

AFM-based single molecule force spectroscopy has been applied to study the detachment of poly(acrylic acid) (PAA) chains preadsorbed onto a silicon nitride tip surface at varied pH. In particular, monolayers of end-grafted chains prepared by nitroxide-mediated polymerization initiated from silica substrates were brought into close contact with the silicon nitride tip of an AFM. The detachment of PAA chains from the tip surface is reflected by a set of constant-force plateaus in the AFM force spectra. From those, comprehensive information about the molecular length distribution of surface-grafted polymers, about their conformation, and about their interaction with the tip as a function of pH is deduced. At neutral pH, the plateau-length distribution well reproduces the molecular weight distribution of the grafted polymers as obtained by GPC. At high pH, increasing electrostatic repulsion between PAA and the tip surface reduces the strength of adsorption, which is manifested in a decrease of average plateau lengths and measured detachment forces. At low pH, complex force spectra and a bimodal distribution of apparent molecular lengths are obtained, reflecting the poor solubility of protonated PAA chains in water as well as polymer−substrate interactions.