A turn-on type vapofluorochromic methoxybenzylidene methanone Schiff base applied to wearable VOC sensor and smartphone-based detection.

This study presents the synthesis, crystallographic data and photophysical properties of a donor-acceptor (D-A) compound, methoxybenzylidene methanone Schiff base (HMPPM). It shows remarkable vapofluorochromism, embodied as turn-on red fluorescence in response to volatile organic compounds (VOCs), with fast response and high signal contrast. HMPPM is further developed into a cellulose sensor via dip-dying method for VOCs detection. We further use RGB and CIELAB color spaces to quantify the vapofluorochromic fluorescence. The limits of detection (LOD) of the sensor reach ppm level. Furthermore, it was fabricated into a wearable VOC sensor, with the introduction of an endogenous/exogenous reference, which conduces to high accuracy and visual identification. The cellulose sensor can be tailored into diversified patterns, with controllable shape and size, which facilitated the encapsulation into various wearables, including shoes, hat and smart band, etc. , succeeding in scenario-based VOCs detection. In addition, we built a smartphone-based sensing platform based on HMPPM , which achieves a ppm-level LOD in VOCs monitoring. [Display omitted] • Turn-on vapofluorochromic effect toward VOCs. • Innovative quantitative method using fluorescent reference with image technology. • Portable VOC sensor compatible with smartphone platform and wearable applications. • Facile synthesis, low-cost preparation, fast response and ppm sensitivity. [ABSTRACT FROM AUTHOR]