Population Control of Thermally Coupled Energy Levels via Energy Transfer in CaWO:Dy/Er Phosphors for High-Sensitivity Ratiometric Thermometer and Multicolor Anticounterfeiting.

The population of thermally coupled energy levels (TCLs) of lanthanide ions (Ln) has a significant impact on their photoluminescence (PL) properties, which are influenced by multiple physical mechanisms, including temperature, crystal field environment, ion concentration, and external excitation conditions, among others. The switchable multicolor emissions of Dy and Er codoped CaWO (CaWO:Dy/Er) phosphors were obtained by varying the doping concentration and excitation wavelength. The excitation wavelength-dependent PL intensities from TCL transitions of Dy and Er, combined with the corresponding fluorescence dynamics of TCLs, confirmed the significant energy transfer (ET) from Dy to Er. Temperature-dependent PL studies demonstrated a substantial discrepancy between the theoretical and calculated energy differences (Δ) of two TCLs, further verifying the influence of the ET process on the Boltzmann population distribution of TCLs. By leveraging the significantly enhanced calculated Δ of TCLs in Dy and Er, the phosphors exhibited an excellent TCL-based ratiometric thermometric performance with high absolute and relative temperature sensitivities. Additionally, the tunable PL color under different excitation wavelengths highlighted their applicability in anticounterfeiting and information encoding applications. This work advances the understanding of the factors that affect the TCL population for optimizing material design and offers novel insights for designing multifunctional luminescent materials for thermometry and secure information encoding.