CdSiO3:Fe3+ nanophosphors: structural and luminescence properties

CdSiO3:Fe3+ nanophosphors: structural and luminescence properties

CdSiO 3 :Fe 3+ (1–9 mol%) nanophosphor was prepared by the propellant combustion technique. The powder X-ray diffraction result shows the formation of highly crystalline nanophosphor monoclinic phase. The average particle size was calculated using Scherrer’s formula and W – H plots were found in the...

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Bibliographic Details
Published in:Bulletin of materials science Vol. 44; no. 1; p. 49
Main Authors: Soppin, Kamala, Manohara, B M
Format: Journal Article
Language:English
Published: Bangalore Indian Academy of Sciences 01-04-2021
Springer Nature B.V
Subjects:
Chemical bonds
Chemistry and Materials Science
Color temperature
Electron microscopes
Energy transfer
Engineering
Ferric ions
Field emission microscopy
Fourier transforms
Infrared spectroscopy
Luminescence
Materials Science
Morphology
Nanophosphors
Nitrates
Optical properties
Particle size
Phosphors
Photoluminescence
Propellant combustion
Raman spectroscopy
Spectrum analysis
X ray powder diffraction
X-ray diffraction
transition electron microscope
Nanophosphor
photoluminescence
energy gap
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Summary:CdSiO 3 :Fe 3+ (1–9 mol%) nanophosphor was prepared by the propellant combustion technique. The powder X-ray diffraction result shows the formation of highly crystalline nanophosphor monoclinic phase. The average particle size was calculated using Scherrer’s formula and W – H plots were found in the range of 22–42 nm. The field emission scanning electron microscope and transmission electron microscope pictures of the particle showed agglomerated, highly porous, lots of voids, irregular shape and uneven in size. Fourier transform infrared and Raman spectroscopy were recorded to investigate the nature of chemical bonds. Energy bandgaps ( E g ) of the prepared samples were estimated using Wood and Tauc relation from the optical UV–Visible spectroscopy and found to be ~5.2 eV. Photoluminescence studies of (1–9 mol%) CdSiO 3 :Fe 3+ nanophosphor shows an intense emission peak at 715 nm when excited at 361 nm. The energy transfer of the excited Fe 3+ ions at higher concentrations are due to concentration quenching. As incorporation concentration of Fe 3+ increases, 4 T 1 (4G) → 6 A 1 transition dominates and the emission intensity increases. Commission International De I’Eclairage and coordinated colour temperature of the phosphors were well located in red region. Therefore, Fe 3+ -doped CdSiO 3 nanophosphor was highly useful for the preparation of red component of WLED’s and solid-state display applications.
ISSN:0250-4707
0973-7669
DOI:10.1007/s12034-020-02332-y