PNNL

Abstract

Two-dimensional materials are of increasing interest for use in filtration, sensing, nanoelectronics, and biomedical devices. Peptoids are a class of biomimetic sequence-defined polymers for which certain amphiphillic sequences self-assemble into 2D crystalline materials with properties that mimic those of cell membranes. Using in situ AFM to both dissect these membrane-like materials and image their subsequent behavior, we explore their ability to self-repair on a range of solid substrates. We show that, in a suitable range of pH, self-repair occurs on both negatively and positively charged substrates and can even occur in the absence of an underlying surface. Following dissection of pre-assembled peptoid membranes and upon introduction of a peptoid monomer solution, peptoids repair the damage by assembling at the newly created edges. The speed of the advancing edge depends on the edge orientation, reflecting the two-fold symmetry of the underlying peptoid lattice. Moreover, because the membranes are stabilized by hydrophobic interactions, if the solution contains peptoids possessing an identical sequence in the hydrophobic block but a distinct hydrophilic block, filling of the defects creates membranes that are patterned at the nanoscale. Consequently, we can utilize this ability to create nm-sized patterns of distinct functional groups within a single coherent membrane.