Molten Salt Synthesis, Characterization and Luminescence Properties of BaAl_1.4Si_0.6O_3.4N_0.6:Eu²⁺Green Phosphors

Abstract: Green emitting BaAl 1.4 Si 0.6 O 3.4 N 0.6 :Eu 2+ phosphors with a uniform sphere-like morphology were successfully prepared via molten salt synthesis (MSS) method using NaNO 3 as the reaction medium. The obtained phosphors exhibited a broad excitation spectrum ranging from 250 to 460 nm and a strong green emission peak at 510 nm due to the 4f 6 5d 1 -4f 7 ( 8 S 7/2 ) transition of Eu 2+ ions. Under excitation at 365 and 450 nm, the optimal emission intensities of the sample obtained by using molten salt are 1… Show more

“… 40,66 The PL spectra profile slightly changed due to a decrease in the peak intensities as the temperature was raised above 403 K. It can be noted that the normalized PL intensities at 423 K still remained 38.2% of their initial intensities at 303 K. This implied that the thermal stability of Ba 2 Lu 4.48 Eu 0.5 La 0.02 B 5 O 17 phosphor further needs to be enhanced. In order to further investigate the relationship between PL intensity and the temperature, the activation energy (Δ E a ) for thermal quenching can be described via the Arrhenius equation as follows: 67,68 where I o is the initial PL intensity and I ( T ) represents the PL intensity at various temperature, k B is the Boltzmann constant (8.629 × 10 −5 eV K −1 ) and A is a constant. Furthermore, the eqn (6) can be rearranged as the following equation: 66,69,70 …”

Photoluminescence properties of novel Ba₂Lu₅B₅O₁₇:Eu³⁺ red emitting phosphors with high color purity for near-UV excited white light emitting diodes

“… 40,66 The PL spectra profile slightly changed due to a decrease in the peak intensities as the temperature was raised above 403 K. It can be noted that the normalized PL intensities at 423 K still remained 38.2% of their initial intensities at 303 K. This implied that the thermal stability of Ba 2 Lu 4.48 Eu 0.5 La 0.02 B 5 O 17 phosphor further needs to be enhanced. In order to further investigate the relationship between PL intensity and the temperature, the activation energy (Δ E a ) for thermal quenching can be described via the Arrhenius equation as follows: 67,68 where I o is the initial PL intensity and I ( T ) represents the PL intensity at various temperature, k B is the Boltzmann constant (8.629 × 10 −5 eV K −1 ) and A is a constant. Furthermore, the eqn (6) can be rearranged as the following equation: 66,69,70 …”

Photoluminescence properties of novel Ba₂Lu₅B₅O₁₇:Eu³⁺ red emitting phosphors with high color purity for near-UV excited white light emitting diodes