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The polycrystalline Eu2+ and Dy 3+ co-doped strontium aluminates SrAl2O4: Eu2+, Dy3+ with different compositions were prepared by solid state reactions. The UV-excited photolumi-nescence, persistent luminescence and thermo-luminescence were studied and compared. Results show that the doped Eu2+ ion in SrAl2O4: Eu2+, Dy3+ phosphors works as not only the UV-excited lumines-cent center but also the persistent luminescent center. The doped Dy3+ ion can hardly yield any lumi-nescence under UV-excitation, but effectively enhance the persistent luminescence and thermo-luminescence of SrAl2O4: Eu2+. Dy3+ co-doping can help form electron traps with appropriate depth due to its suitable electro-negativity, and increase the density and depth of electron traps. Based on above observations, a persistent luminescence mechanism, electron transfer model, is proposed and illustrated.
The polycrystalline Eu2 + and Dy3 + co-doped strontium aluminates SrAl2O4: Eu2 +, Dy3 + with different compositions were prepared by solid state reactions. The UV-excited photoluminescent nescence, persistent luminescence and thermo-luminescence were studied and compared. doped Eu2 + ion in SrAl2O4: Eu2 +, Dy3 + phosphors works as not only the UV-excited lumines-cent center but also the persistent luminescent center. The doped Dy3 + ion can hardly yield any lumi- nescence under UV-excitation, but effectively enhance the persistent luminescence and thermo-luminescence of SrAl2O4: Eu2 +. Dy3 + co-doping can help form electron traps with appropriate depth due to its suitable electro-negativity, and increase the density and depth of electron traps. Based on above observations, a persistent luminescence mechanism, electron transfer model, is proposed and illustrated.