Light-Gated Control of Conformational Changes in Polymer Brushes

Herein, a strategy to control conformational changes in grafted polymer brushes via photoinduced crosslinking of photoreactive groups embedded into the lateral architecture of a polymer brush is reported. Poly(methylmethacrylate)-based polymer brushes containing UV-light (lambda = 325 nm) photoreactive o-methyl benzaldehyde moieties are synthesized using surface-initiated reversible deactivation polymerization. The conformational changes in polymer brushes upon UV-light triggered crosslinking are comprehensively analyzed through a full suite of surface sensitive characterization methods including time of flight secondary ion mass spectrometry, quartz crystal microbalance with dissipation monitoring, UV/vis spectroscopy, atomic force microscopy, nanoplasmonic sensing, and neutron reflectometry. The spatiotemporal control of the induced conformational changes is demonstrated via photolithography experiments. To enable an additional level of control, a second gate, the visible light (lambda = 445 nm) active styrylpyrene moiety, is incorporated into the polymer brush architecture. Critically, wavelength-selective crosslinking behavior is observed in the diblock copolymer structures allowing to crosslink specific sections of the lateral brush architecture as a function of irradiation wavelength.

Automated summary

This study presents a strategy to control conformational changes in grafted polymer brushes through photoinduced crosslinking of photoreactive groups embedded in the lateral architecture. The polymer brushes containing UV-light photoreactive o-methyl benzaldehyde moieties were synthesized using surface-initiated reversible deactivation polymerization and the conformational changes were analyzed comprehensively using various surface sensitive characterization methods. By incorporating a visible light active moiety into the polymer brush architecture, wavelength-selective crosslinking behavior was observed, allowing for specific sections of the lateral brush architecture to be crosslinked based on irradiation wavelength.