A solid-state reaction method was used to synthesize Dy3+/Eu3+ co-activated Na4Ca4Si6O18 phosphors, and their structural, morphological, and luminescence properties were investigated. X-ray diffraction confirmed the phase purity of the material. The NCMS phosphors co-activated with Dy3+/Eu3+ ions exhibited a high energy transfer efficiency of up to 97.80%. The Dy3+-activated NCMS phosphor showed a color shift from yellow to red by varying the Eu3+ ion concentration, and also displayed excellent thermal stability. The Dy3+/Eu3+ co-doped NCMS phosphors have potential applications in lighting and display technologies due to their excellent thermal stability and flexible color tunability.
A solid-state reaction methodology has been adopted to synthesize Dy3+ (dysprosium)/Eu3+ (europium) co-activated Na4Ca4Si6O18 (NCMS) phosphors. The structural, morphological, and luminescence characteristics of the prepared materials have been investigated. The phase purity of the material was confirmed by X-ray diffraction (XRD) by comparing the diffraction peaks with the JCPDS standard pattern (JCPDS card no. 75-1687). The photoluminescence (PL) spectra of NCMS phosphors activated with Dy3+ and co-activated with Dy3+ (sensitizer)/Eu3+ (activator) ions were investigated. The as-prepared NCMS phosphors co-activated with Dy3+/Eu3+ ions were excited with near-ultraviolet light (& lambda;(ex) = 348 nm) and showed the utmost energy transfer of up to 97.80% from sensitizer to activator. Dexter and Reisfeld's approximation specifically confirms that the energy transfer from sensitizer to activator was through electric dipole-dipole interactions. The Dy3+-activated NCMS phosphor showed an illumination shift from yellow to red by varying the Eu3+ ion concentration and colour tunability is also observed by altering the excitation energy. The emission intensity was sustained up to 92.21% at 423 K (& SIM;150 & DEG;C), indicating an excellent thermal stability of the bi-activated NCMS phosphor. The Dy3+/Eu3+ co-doped NCMS phosphors display excellent thermal stability with flexible color tunability to emerge as promising contenders in the field of lighting and display technologies.
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