Solar‐Blind Ultraviolet Organic Mechanoluminescent Materials

Organic mechanoluminescent (ML) materials have attracted intensive attention for their potential applications in real‐time stress sensing and structural damage monitoring. To avoid interference from daylight or artificial lighting sources, the ML‐based sensors can be only used in dark‐field scenarios, which becomes the most serious limitation for their development. Herein, we proposed a new strategy that adjusts the ML spectra to the solar‐blind ultraviolet region to address this challenge. By strategically breaking the molecular conjugation and adjusting the packing mode, a series of diphenylphosphine oxide derivatives were successfully designed. To our delight, the shortest ML emission, among all reported organic ML materials, with the maxima at ca. 293 nm (in solar‐blind UV region) was achieved. Photophysical studies, single crystal analysis and theoretical calculations were performed to investigate the solar‐blind UV ML properties. Furthermore, wide‐range color‐tunable ML emissions spanning from 293 nm to 741 nm were achieved. Under various external stimuli such as stretching, folding, and vehicle impact in daylight, obvious ML signals could be directly recorded, and the quantitative relationship between the mechanical stimuli and the ML intensities was also studied. This work suggests a feasible strategy to realize solar‐blind UV ML materials and makes bright‐field environment ML sensors possible.