Abstract
Urea-assisted solution combustion (SC) synthetic method is employed to prepare a series of yellowish-white light emitting Dy3+doped Gd4Al2O9 (x = 1–6 mol%) phosphors. Phase identification and refinement parameters of designated nanomaterials are analyzed by means of Rietveld refinement technique. All doped samples are structured into monoclinic crystal system with P21c space group. Scherrer's formula and Williamson-Hall (W-H) linearly fitted method are employed to enumerate the crystallite size that are observed in the domain of nano-scale. The transmission spectrum of diffused reflectance is utilized to calculate the optical energy band gap of optimized sample Gd3.97Dy0.03Al2O9 that come out to be 5.11 eV. TEM micrograph discloses the existence of non-uniform agglomerated particles. The photophysical characteristics of doped phosphors are analyzed by exploiting their photoluminescence excitation (PLE) and emission profiles. The most intense excitation peak is found to be at 351 nm, which is meticulously harmonized with the distinctive wavelength of commercialized near ultra-violet (NUV) based LED chips. The emission profile of all doped samples possesses sharp emission lines centered at 481, 573, and 667 nm, which are ascribed to 4F9/2→6H15/2, 4F9/2→6H13/2, and 4F9/2→6H11/2 intraconfigurational transitions of Dy3+ ion, correspondingly. The emission decay curves are well fitted with bi-exponential function and in good agreement with findings of the refinement analysis viz. existence of two non-centrosymmetric sites attained by the Dy3+ ions. Auzel's model is used to estimate the radiative lifetime (τR= 5.14356 ± 0.65104 ms). The chromaticity coordinates and correlated color temperature (CCT) values for all doped samples are found close to standard white coordinates, thus proved them a potential candidate in single-phase phosphor converted WLEDs.
Published Version
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