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Toward Accurate Measurement of Intrinsic Quantum Yield of Lanthanide Complexes with Back Energy Transfer

Abstract

Trivalent lanthanide complexes are an important class of luminescent material characterized by their strong absorption of light by the organic ligands and subsequent energy transfer to the lanthanide ion, realizing intense luminescence from the ion. With this mechanism of luminescence, the total quantum yield of a lanthanide complex is the product of energy transfer efficiency from the ligand to the lanthanide ion and the “intrinsic” quantum yield of lanthanide ion itself. The “absolute” method in measuring quantum yield uses an integrating sphere, and this method can be used for measuring both the total and the intrinsic quantum yields. The presence of back energy transfer (the reverse process of the energy transfer) adds complication to this by affecting both the dynamics of the excited state of the ligands and the lanthanide ion. Herein, we theoretically derive an equation that shows in the presence of back energy transfer the intrinsic quantum yield may differ depending on whether it is determined from the measurement through excitation of ligands or lanthanide directly. The measured value by direct lanthanide excitation could decrease to 20% or less of the actual value when back energy transfer is prominent. Several previously reported Tb(III) complexes are within the range to be cautious. This report shows that the “absolute” method for measuring lanthanide ion-centered quantum yield may not be suitable in the presence of back energy transfer by principle. We also provide a possible workaround in the case several approximations and assumptions can be made.

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Article information


Submitted
21 Nov 2019
Accepted
13 Jan 2020
First published
14 Jan 2020

Phys. Chem. Chem. Phys., 2020, Accepted Manuscript
Article type
Paper

Toward Accurate Measurement of Intrinsic Quantum Yield of Lanthanide Complexes with Back Energy Transfer

S. Omagari and M. Vacha, Phys. Chem. Chem. Phys., 2020, Accepted Manuscript , DOI: 10.1039/C9CP06294G

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