Direct Observations of Segmental Dynamics at the Polymer-Substrate Interface Enabled by Localizing Fluorescent Probes with Polymer Brushes

We employed imaging rotational fluorescence correlation microscopy to directly observe the segmental dynamics of the polymer near the polymer-substrate interface using a probe-tethered polymer brush buried in bulk polymer films. The probe-tethered polymers grafted onto the polymer-substrate interface provide spatial selectivity to probe only the segmental dynamics of polymer near the polymer-substrate interface. The perturbation caused by the grafted polymer chains on the segmental dynamics of the polymer film near the interface was minimized by reducing the molecular weight of the polymer brush compared with the critical entanglement molecular weight of the polymer and grafted with a low grafting density (approximate to 0.1 chains/nm(2)) using a grafting-to method, which allows precisely controlled and fully characterized polymer brush structures. In addition, the molecular weight of the brush polymer was further controlled to approximate to 10 kg/mol with the root-mean-square end-to-end distance of approximate to 5 nm to probe dynamics within 10 nm of the polymer-substrate interface. Polystyrene and poly(methyl methacrylate) films carrying rather unfavorable and similar surface energies, respectively, with the silane-modified silicon wafer substrates were investigated. The polymer dynamics near the interface characterized by the degrees of non-Arrhenius temperature dependence and nonexponential relaxation were not altered in both systems compared with those of the bulk, suggesting that the polymer dynamics is not sensitive to moderate differences in enthalpic interaction between the polymer and the substrate.

Automated summary

Imaging rotational fluorescence correlation microscopy was used to directly observe the segmental dynamics of a polymer near the polymer-substrate interface. The probe-tethered polymer brush provided spatial selectivity to probe only the segmental dynamics near the interface. The perturbation caused by the grafted polymer chains on the segmental dynamics of the polymer film was minimized by reducing the molecular weight of the polymer brush and using a low grafting density. The polymer dynamics near the interface were found to be insensitive to moderate differences in enthalpic interaction between the polymer and the substrate.