Alignment layers based on poly(oxadiazole-naphthylimide)s: New aspects on tuning anisotropy of the surface morphology and adhesion via rubbing

Two poly(oxadiazole-naphthylimide) films are prepared and characterized to elucidate their suitability as alignment layers for nematics in display devices. First, rheological behavior is analyzed to establish in correlation with molecular modeling the optimal conditions of solution shearing to obtain uniform films by spin coating. Second, the polymer foils are subjected to rubbing with cellulose diacetate cloth to induce surface anisotropy required for nematic orientation. Novel insights are extracted here by studying the effect induced by the positioning of the textile fiber parallel/orthogonal to the rubbing direction on the induced polymer morphology through atomic force microscopy. The balance between the isotropic and anisotropic characters of the surface morphology of the unrubbed and rubbed polyimide (PI) samples is evaluated by Fourier spectrum integrated into polar coordinates and autocorrelation function analysis. The involvement of the created surface features on the anisotropy of the interfacial PI/nematic adhesion is further investigated. The qualitative orientation ability of the surface textured samples is evaluated revealing that both PI chain flexibility and fiber positioning are paramount for attaining uniform orientation of the nematic. These aspects are key factors in advancing modern displays via proper surface/bulk processing of the alignment layer.

Automated summary

Two poly(oxadiazole-naphthylimide) films are prepared and characterized for their suitability as alignment layers for nematics; rheological behavior is analyzed to establish optimal conditions for solution shearing; rubbing with cellulose diacetate cloth is used to induce surface anisotropy and molecular morphology is studied using atomic force microscopy.