Energy migration and Gd3+ ↔ Ce3+ transfer in Ce3+-doped GdP3O9 metaphosphate

Luminescence-kinetics studies of Ce3+-doped GdP3O9 metaphosphate, which was prepared by a melt-solution technique, are performed using time-resolved luminescence spectroscopy techniques at T = 4.2-300 K. The processes of energy migration along the Gd3+ sub-lattice and energy transfer between Gd3+ an...

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Bibliographic Details
Published in:Journal of physics. D, Applied physics Applied physics, 2013-06, Vol.46 (23)
Main Authors: Demchenko, P, Gektin, A, Krasnikov, A, Pashuk, I, Shalapska, T, Stryganyuk, G, Voloshinovskii, A, Zazubovich, S
Format: Article
Language:English
Subjects:
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Exact sciences and technology
Optical properties and condensed-matter spectroscopy and other interactions of matter with particles and radiation
Other solid inorganic materials
Photoluminescence
Physics
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Summary:Luminescence-kinetics studies of Ce3+-doped GdP3O9 metaphosphate, which was prepared by a melt-solution technique, are performed using time-resolved luminescence spectroscopy techniques at T = 4.2-300 K. The processes of energy migration along the Gd3+ sub-lattice and energy transfer between Gd3+ and Ce3+ ions are investigated. At low temperatures, the emission of Gd3+ is caused by the radiative decay of its lowest-energy relaxed excited 6P7/2 state, and the Gd3+ → Ce3+ energy transfer is absent. As the temperature increases, the thermally stimulated population of the higher energy 6P5/2, 6P3/2 levels of the Gd3+ 6PJ-excited state takes place, which reveals itself in a higher energy shift of the Gd3+ 6PJ → 8S7/2 emission band. The phonon-assisted population of the Gd3+ 6P5/2 excited level at T < 150 K is suggested to be responsible for the increase in probability of energy migration along the Gd3+ sub-lattice followed by the Gd3+ → Ce3+ energy transfer. The more effective Gd3+ → Ce3+ energy transfer at T > 150 K takes place owing to the thermally stimulated population of the highest-energy 6P3/2 excited level together with the lower energy shift of the Ce3+ 4f-5d1 absorption band. Unlike the Gd3+ → Ce3+ transfer, the reverse Ce3+ → Gd3+ energy transfer is observed at any temperature.
ISSN:0022-3727
1361-6463
DOI:10.1088/0022-3727/46/23/235103