Modeling blue to UV upconversion in β-NaYF4:Tm(3)

Pedro Villanueva-Delgado; Karl W Krämer; Rafael Valiente; Mathijs de Jong; A Meijerink

doi:10.1039/c6cp04347j

Modeling blue to UV upconversion in β-NaYF4:Tm(3)

Pedro Villanueva-Delgado, Karl W Krämer, Rafael Valiente, Mathijs de Jong, A Meijerink

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Samples of 0.01% and 0.3% Tm(3+)-doped β-NaYF4 show upconverted UV luminescence at 27 660 cm(-1) (361 nm) after blue excitation at 21 140 cm(-1) (473 nm). Contradictory upconversion mechanisms in the literature are reviewed and two of them are investigated in detail. Their agreement with emission and two-color excitation experiments is examined and compared. Decay curves are analyzed using the Inokuti-Hirayama model, an average rate equation model, and a microscopic rate equation model that includes the correct extent of energy transfer. Energy migration is found to be negligible in these samples, and hence the average rate equation model fails to correctly describe the decay curves. The microscopic rate equation model accurately fits the experimental data and reveals the strength and multipolarity of various interactions. This microscopic model is able to determine the most likely upconversion mechanism.

Original language	English
Pages (from-to)	27396-27404
Number of pages	9
Journal	Physical Chemistry Chemical Physics
Volume	18
Issue number	39
DOIs	https://doi.org/10.1039/c6cp04347j
Publication status	Published - 2016

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title = "Modeling blue to UV upconversion in β-NaYF4:Tm(3)",

abstract = "Samples of 0.01% and 0.3% Tm(3+)-doped β-NaYF4 show upconverted UV luminescence at 27 660 cm(-1) (361 nm) after blue excitation at 21 140 cm(-1) (473 nm). Contradictory upconversion mechanisms in the literature are reviewed and two of them are investigated in detail. Their agreement with emission and two-color excitation experiments is examined and compared. Decay curves are analyzed using the Inokuti-Hirayama model, an average rate equation model, and a microscopic rate equation model that includes the correct extent of energy transfer. Energy migration is found to be negligible in these samples, and hence the average rate equation model fails to correctly describe the decay curves. The microscopic rate equation model accurately fits the experimental data and reveals the strength and multipolarity of various interactions. This microscopic model is able to determine the most likely upconversion mechanism.",

author = "Pedro Villanueva-Delgado and Kr{\"a}mer, {Karl W} and Rafael Valiente and {de Jong}, Mathijs and A Meijerink",

year = "2016",

doi = "10.1039/c6cp04347j",

language = "English",

volume = "18",

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issn = "1463-9076",

publisher = "Royal Society of Chemistry",

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T1 - Modeling blue to UV upconversion in β-NaYF4:Tm(3)

AU - Villanueva-Delgado, Pedro

AU - Krämer, Karl W

AU - Valiente, Rafael

AU - de Jong, Mathijs

AU - Meijerink, A

PY - 2016

Y1 - 2016

N2 - Samples of 0.01% and 0.3% Tm(3+)-doped β-NaYF4 show upconverted UV luminescence at 27 660 cm(-1) (361 nm) after blue excitation at 21 140 cm(-1) (473 nm). Contradictory upconversion mechanisms in the literature are reviewed and two of them are investigated in detail. Their agreement with emission and two-color excitation experiments is examined and compared. Decay curves are analyzed using the Inokuti-Hirayama model, an average rate equation model, and a microscopic rate equation model that includes the correct extent of energy transfer. Energy migration is found to be negligible in these samples, and hence the average rate equation model fails to correctly describe the decay curves. The microscopic rate equation model accurately fits the experimental data and reveals the strength and multipolarity of various interactions. This microscopic model is able to determine the most likely upconversion mechanism.

AB - Samples of 0.01% and 0.3% Tm(3+)-doped β-NaYF4 show upconverted UV luminescence at 27 660 cm(-1) (361 nm) after blue excitation at 21 140 cm(-1) (473 nm). Contradictory upconversion mechanisms in the literature are reviewed and two of them are investigated in detail. Their agreement with emission and two-color excitation experiments is examined and compared. Decay curves are analyzed using the Inokuti-Hirayama model, an average rate equation model, and a microscopic rate equation model that includes the correct extent of energy transfer. Energy migration is found to be negligible in these samples, and hence the average rate equation model fails to correctly describe the decay curves. The microscopic rate equation model accurately fits the experimental data and reveals the strength and multipolarity of various interactions. This microscopic model is able to determine the most likely upconversion mechanism.

U2 - 10.1039/c6cp04347j

DO - 10.1039/c6cp04347j

M3 - Article

C2 - 27722287

SN - 1463-9076

VL - 18

SP - 27396

EP - 27404

JO - Physical Chemistry Chemical Physics

JF - Physical Chemistry Chemical Physics

IS - 39

ER -

Modeling blue to UV upconversion in β-NaYF4:Tm(3)

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