Repairable Macroscopic Monodomain Arrays from Block Copolymers Enabled by Photoplastic and Photodielectric Effects.

Upon exposure to UV light (120 mW/cm 2 , λ = 365 nm), a trans - cis isomerization occurs in a cylinder-forming, azobenzene-containing block copolymer of polydimethylsiloxane- b -poly((4(phenyldiazenyl)phenoxy)hexyl acrylate) (PDMS- b -PPHA) that enables the generation of monodomains of healable, long-range ordered arrays of nanoscopic domains over macroscopic distances. The trans - cis isomerization gives rise to a significant increase in the dielectric constant (from 6.52 to 19.8 at 100 Hz, photodielectric behavior) and a dramatic decrease in the T g (from 54 to 1 °C, photoplastic behavior) of the PPHA block. By combining these characteristics with an in-plane electric field, macroscopic monodomains of near-perfectly aligned cylindrical microdomains are achieved at low temperatures, and a damage repair is clearly uncovered, where the 300 nm wide scratches can be completely healed at 40 °C, leaving a smooth, uniformly thick film where the continuity and orientation of the aligned microdomains are restored. Subsequent exposure to visible light causes a cis-trans isomerization, increasing the matrix T g to 54 °C, producing highly oriented and aligned PDMS cylindrical microdomains in a PPHA matrix.