image: The upper picture is the luminescence mechanism diagram of PBA3[InCl6]·H2O, and the lower figure is the information encryption application diagram
Credit: ©Science China Press
This study is led by Prof. Hongbing Fu and Prof. Yang Tian (Department of Chemistry, Capital Normal University). The experiments were performed by an Edinburgh FLS-1000 fluorescence spectrometer combined with theoretical calculations.
Interestingly, the study found that PBA3[InCl6]·H2O exhibits a special "herringbone" stacking mode that enables abundant weak interactions between organic ligands and metal halide units. While the light source with 420 nm wavelength is used for excitation, the crystals preferentially display the ultra-long triplet phosphorescent emission with 290.4 ms lifetime decay.
“DFT calculation shows that PBA3[InCl6]·H2O is a direct band gap semiconductor. Due to the abundant weak interactions between metal octahedral and organics in the crystal, there is an energy or electron transfer between the inorganic anions and organic cations during the photo-excitation process. The [InCl6]3- octahedron helps to stabilize the triplet excitons prompting the production of extra-long phosphorescence with more than 7 s to the naked eye.” Tian says.
By designing patterns for encryption systems, the material further demonstrates the potential of the field of information encryption. It is worth mentioning that PBA3[InCl6]·H2O also has excellent stability in the air environment, laying the foundation for various commercial applications in the future.
See the article:
Ultra-long Room Temperature Phosphorescence of Indium-based Organic Inorganic Metal Halide for Naked-eye-visible Afterglow
https://doi.org/10.1007/s11426-023-1721-4
Journal
Science China Chemistry