Energy transfer based emission analysis of (Tb3+, Sm3+): Lithium zinc phosphate glasses

“…For Ho 3+ single doped glass SFAC: 0.8H, eight absorption bands peaking at ~361, 386, 418, 453, 472, 485, 537, and 641 nm are clearly distinguished, which are attributed to the excitation from 5 I 8 ground state to the 3 H 6 , 5 G 4 , 5 G 5 , 5 G 6 + 5 F 1 , 5 F 2 , 5 F 3 , 5 S 2 + 5 F 4 , and 5 F 5 excited states of Ho 3+ ions, respectively. For the Sm 3+ single doped glass SFAC: 0.1S, the absorption peak at 401 nm is induced by the electronic transition 6 H 5/2 → 4 F 7/2 of Sm 3+ ions . The absorption spectrum of SFAC: 0.1C is due to the 4f → 5d electronic transition of Ce 3+ ions.…”

Near white light emission of Ce³⁺‐, Ho³⁺‐, and Sm³⁺‐doped oxyfluoride silicate glasses

“…For Ho 3+ single doped glass SFAC: 0.8H, eight absorption bands peaking at ~361, 386, 418, 453, 472, 485, 537, and 641 nm are clearly distinguished, which are attributed to the excitation from 5 I 8 ground state to the 3 H 6 , 5 G 4 , 5 G 5 , 5 G 6 + 5 F 1 , 5 F 2 , 5 F 3 , 5 S 2 + 5 F 4 , and 5 F 5 excited states of Ho 3+ ions, respectively. For the Sm 3+ single doped glass SFAC: 0.1S, the absorption peak at 401 nm is induced by the electronic transition 6 H 5/2 → 4 F 7/2 of Sm 3+ ions . The absorption spectrum of SFAC: 0.1C is due to the 4f → 5d electronic transition of Ce 3+ ions.…”

Near white light emission of Ce³⁺‐, Ho³⁺‐, and Sm³⁺‐doped oxyfluoride silicate glasses

“…Our experimental results indicated that energy transfer occurs between Tb 3+ and Sm 3+ ions. Spectral overlapping between the Sm 3+ absorption and the Tb 3+ emission spectra shows that the energy transfer occurs from Tb 3+ to Sm 3+ [43]. It's known that the absorption band around 477 nm of Sm 3+ ion overlap with the emission band of Tb 3+ around 488 nm [35].…”

Study on luminescent properties of Tb³⁺ and Sm³⁺ co-doped CaSiO₃ phosphors for white light emitting diodes

“…The value of η Dy /η Dy-Eu ratio can be approximated to the ratio of emission intensities (I Dy /I Dy-Eu ) and decay lifetimes (τ Dy /τ Dy-Eu ) for the present co-doping system. Therefore, using the decay lifetimes, the relations can be written as Equation (4) 59,63,64 : ), where n stands for 6, 8, and 10. The lifetimes versus concentration result showed a linear trend for n = 6, 8, and 10, with the best fit for n = 6, demonstrating the electric dipole-dipole interaction is liable for ET from Dy 3+ to Eu 3+ in the KZnBP glass.…”

“…The value of η Dy / η Dy‐Eu ratio can be approximated to the ratio of emission intensities ( I Dy / I Dy‐Eu ) and decay lifetimes ( τ Dy / τ Dy‐Eu ) for the present co‐doping system. Therefore, using the decay lifetimes, the relations can be written as Equation () 59,63,64 : $$$$\begin{equation}{\tau }_{{\rm{Dy}}}/{\tau }_{{\rm{Dy}} - {\rm{Eu}}} \propto {C}^{n/3},\end{equation}$$$$where τ Dy and τ Dy–Eu refer to the Dy 3+ lifetimes, co‐doped without and with Eu 3+ , respectively. The graph between $${\tau }_{{\rm{D}}( {{\rm{Dy}}^{3 + }} )}/{\tau }_{{\rm{D}}( {{\rm{Dy}}^{3 + }} ) - {\rm{A\ }}( {{\rm{Eu}}^{3 + }} )}$$$${\rm{\ and}}\ $$$$C_{{\rm{D}}( {{\rm{Dy}}^{3 + }} ) + {\rm{A}}( {{\rm{Eu}}^{3 + }} )}^{n/3}$$ was used to determine the multipole–multipole interaction, facilitating the ET process.…”

Excitation‐dependent energy transfer and color tunability in Dy³⁺/Eu³⁺ co‐doped multi‐component borophosphate glasses