Solid-State Emission Enhancement via Molecular Engineering of Benzofuran Derivatives.

A series of linear benzofuran derivatives consisting of either a vinylene or a cyanovinylene were prepared in order to investigate their emission properties. The X-ray crystallography of structurally similar derivatives was also evaluated. The crystalline structures of the vinylene derivatives showed only lateral contacts that involved the benzofurans and no π-stacking. In contrast, π-stacking was observed for the bisbenzofuran and benzofuran-phenyl cyanovinylene derivatives. No intermolecular π-π stacking was observed for the extended cyanovinylene structures. Intermolecular bonding between the nitrile and a furan atom was found. The fluorescence quantum yields (Φ) of the vinylene derivatives were consistently high (>50%) in both solution and the crystal state. The exception was the benzofuran-furan-vinylene-phenyl, the Φ of which was <10% when in the solid state. The cyanovinylene counterparts emitted weakly in solution (Φ < 2%). Their luminogenic property was demonstrated with a ca. 15-fold increase in emission in the solid state. A 6-fold emission enhancement was also found when they were aggregated in a 90 vol% methanol/water mixture. The solid-state emission enhancement of the cyanovinylene benzofurans was in part attributable to intermolecular contacts that suppressed excited-state deactivation by molecular motion.