Modulating Smart Mechanoluminescent Phosphors for Multistimuli Responsive Optical Wood

Mechanoluminescence is a smart light-emitting phenomenon in which applied mechanical energy is directly converted into photon emissions. In particular, mechanoluminescent materials have shown considerable potential for applications in the fields of energy and sensing. This study thoroughly investigates the mechanoluminescence and long afterglow properties of singly doped and codoped Sr2MgSi2O7(SMSO) with varying concentrations of Eu2+ and Dy3+ ions. Subsequently, a comprehensive analysis of its multimode luminescence properties, including photoluminescence, mechanoluminescence, long afterglow, and X-ray-induced luminescence, is conducted. In addition, the density of states mapping is acquired through first-principles calculations, confirming that the enhanced mechanoluminescence properties of SMSO primarily stem from the deep trap introduced by Dy3+. In contrast to traditional mixing with Polydimethylsiloxane, in this study, the powders are incorporated into optically transparent wood to produce a multiresponse with mechanoluminescence, long afterglow, and X-ray-excited luminescence. This structure is achieved by pretreating natural wood, eliminating lignin, and subsequently modifying the wood to overall modification using various smart phosphors and epoxy resin composites. After natural drying, a multifunctional composite wood structure with diverse luminescence properties is obtained. Owing to its environmental friendliness, sustainability, self-power, and cost-effectiveness, this smart mechanoluminescence wood is anticipated to find extensive applications in construction materials and energy-efficient displays.

Automated summary

Mechanoluminescence and long afterglow properties of Sr2MgSi2O7(SMSO) singly doped and codoped with Eu2+ and Dy3+ ions are thoroughly investigated in this study. Comprehensive analysis of its multimode luminescence properties is conducted, including photoluminescence, mechanoluminescence, long afterglow, and X-ray-induced luminescence. First-principles calculations confirm that the enhanced mechanoluminescence properties of SMSO primarily derive from the deep trap introduced by Dy3+. In contrast to traditional mixing, this study incorporates the powders into optically transparent wood, achieving a multiresponse with mechanoluminescence, long afterglow, and X-ray-excited luminescence.