H. Desirena scite author profile

Structural and upconversion emission properties of ZrO2:Yb3+–Ho3+ nanocrystals were analyzed as function of Yb3+ concentration. Structural characterization shows a crystallite size up to 80 nm and tetragonal and cubic phase as the main crystalline structures. Strong green (540 nm) and weak red (670 nm) and near infrared (760 nm) emission bands were observed with 968 nm excitation. The upconversion is based on two photons absorption either by the energy transfers from Yb3+ ion or by the excited state absorption. The energy transfer efficiency was calculated to be 50% for 2 mol % of Yb3+ diminishing to less than 20% for higher concentration. The Yb3+ concentration also affects the decay time of the green emission of Ho3+ ion diminishing from 140μs for 2 mol % of Yb to 76μs for higher concentration.

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Luminescence Concentration Quenching Mechanism in Gd₂O₃:Eu³⁺.

Meza

et al. 2014

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Luminescence concentration quenching in Gd2O3:Eu(3+) nanocrystals results from strong interactions among O(2-) ions and Eu(3+) ions. Because all synthesized Gd2O3:Eu(3+) nanocrystals present the same cubic crystalline phase regardless of Eu(3+) concentration, it is possible to study the optical properties as a function of the dopant concentration. The emission intensities and lifetime curves for Gd2O3:Eu(3+) were analyzed by a simple rate equation model to study the interaction between the O(2-) ions and Eu(3+) ions. The rate equation model considers that such interaction is driven by the following energy transfer processes: the direct energy transfer (O(2-) → Eu(3+)), back-transfer (Eu(3+) → O(2-)), and direct energy migration (Eu(3+) → Eu(3+)). The exact solution of this model agrees with the experimental results, luminescence concentration quenching is reproduced and the corresponding energy transfer rates are reported. Quantitative results suggest that the direct energy transfer and direct energy migration processes are the main responsible for the luminescence concentration quenching, whereas the back-transfer process promotes the Eu(3+) emission.

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Concentration effect of Er3+ ion on the spectroscopic properties of Er3+ and Yb3+/Er3+ co-doped phosphate glasses

et al. 2006

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Radiative and non radiative spectroscopic properties of Er3+ ion in tellurite glass

Kumar

Rosa

Desirena

2006

Optics Communications

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Effect of alkali metal oxides R2O (R=Li, Na, K, Rb and Cs) and network intermediate MO (M=Zn, Mg, Ba and Pb) in tellurite glasses

Desirena¹,

Schülzgen²,

Sabet³

et al. 2009

Optical Materials

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H. Desirena

Strong green upconversion emission in ZrO2:Yb3+–Ho3+ nanocrystals

Luminescence Concentration Quenching Mechanism in Gd₂O₃:Eu³⁺.

Concentration effect of Er3+ ion on the spectroscopic properties of Er3+ and Yb3+/Er3+ co-doped phosphate glasses

Radiative and non radiative spectroscopic properties of Er3+ ion in tellurite glass

Effect of alkali metal oxides R2O (R=Li, Na, K, Rb and Cs) and network intermediate MO (M=Zn, Mg, Ba and Pb) in tellurite glasses

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H. Desirena

Strong green upconversion emission in ZrO2:Yb3+–Ho3+ nanocrystals

Luminescence Concentration Quenching Mechanism in Gd2O3:Eu3+.

Concentration effect of Er3+ ion on the spectroscopic properties of Er3+ and Yb3+/Er3+ co-doped phosphate glasses

Radiative and non radiative spectroscopic properties of Er3+ ion in tellurite glass

Effect of alkali metal oxides R2O (R=Li, Na, K, Rb and Cs) and network intermediate MO (M=Zn, Mg, Ba and Pb) in tellurite glasses

Contact Info

Product

Resources

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Luminescence Concentration Quenching Mechanism in Gd₂O₃:Eu³⁺.