Blue Light Hazard Optimization for White Light-Emitting Diode of Mn2+-Activated 0D Cs3Cu2Br5 Perovskite Materials

The zero-dimensional perovskite-like derivative Cs3Cu2X5 (X = Cl, Br, I) with self-trapped excitons (STEs) photoluminescence (PL) has attracted tremendous interest in the field of optoelectronics. Nonetheless, it is challenging for Cs3Cu2Br5 material to attain full visible spectrum emission and prevent light-induced photochemical damage to the retina (blue light hazard) in applications. Herein, Mn2+ is chosen as the dopant to alloy into Cs3Cu2X5 via a one-step solid state synthesis method. Significantly, the series of Mn2+-doped show the emission peak of 460 nm STEs and the emission peak of 550 nm Mn2+. More importantly, the high energy absorption of Mn2+ facilitates the transfer of exciton energy, contributing to a reduction in blue emission peak at 460 nm. Simultaneously, approximate to 17.5% of Mn2+ is alloyed into the Cs(3)Cu(2)X(5)lattice to induce the energy transfer channels from the Cs3Cu2X5 host to the Mn2+ guest to lead to the emission of Mn2+, which broadens emission spectrum (400-620 nm) and realizes 80% reduction of the blue emission peak at 460 nm. Additionally, a white light-emitting diodes can decrease the blue emission band via 71.45% and an ultrahigh color rendering index (CRI) of 94.5 is produced using the 17.5% Mn2+: Cs3Cu2X5 perovskite-like derivative powder material.