Phase stability and oxygen-sensitive photoluminescence of ZrO2:Eu,Nb nanopowders

We studied structure and oxygen-sensitive photoluminescence (PL) of ZrO2:Eu,Nb nanocrystalline powders synthesized via a sol-gel route and heat-treated up to 1200 °C. The material containing only 2 at% Eu3+ was predominantly monoclinic, whereas 8 at% of Eu3+ stabilized tetragonal phase. Comparable a...

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Published inMaterials chemistry and physics Vol. 214; pp. 135 - 142
Main Authors Kiisk, Valter, Puust, Laurits, Mändar, Hugo, Ritslaid, Peeter, Rähn, Mihkel, Bite, Ivita, Jankovica, Dzidra, Sildos, Ilmo, Jaaniso, Raivo
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.08.2018
Subjects
Charge compensation
Europium
Oxygen sensing
Photoluminescence
Zirconium dioxide
Charge compensation
Oxygen sensing
Zirconium dioxide
Europium
Photoluminescence
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Summary:We studied structure and oxygen-sensitive photoluminescence (PL) of ZrO2:Eu,Nb nanocrystalline powders synthesized via a sol-gel route and heat-treated up to 1200 °C. The material containing only 2 at% Eu3+ was predominantly monoclinic, whereas 8 at% of Eu3+ stabilized tetragonal phase. Comparable amount of niobium co-doping effectively suppressed the formation of tetragonal phase. PL of Eu3+ ions was observed under direct excitation at 395 nm. PL decay kinetics showed that the luminescence was partially quenched, depending on doping concentrations and ambient atmosphere. At 300 °C, the PL intensity of all samples systematically responded (with up to 70% change) to changing oxygen content in the O2/N2 mixture at atmospheric pressure. At low doping levels, the dominant factor controlling the PL intensity was an energy transfer from excited PL centers to randomly distributed defects in the ZrO2 lattice. We argue that the charge transfer between the defects and adsorbed oxygen molecules alters the ability of the defects to quench Eu3+ luminescence. At high doping levels, another type of sensor response was observed, where some Eu3+ emitters are effectively switched on or off by the change of ambient gas. A remarkable feature of the studied material is a reversing of the sensor response with the variation of the Nb concentration. •Charge compensation of Eu3+ ions in ZrO2 by Nb5+ ions is proposed.•Simultaneous doping with Eu3+ and Nb5+ ions suppresses the formation of tetragonal ZrO2.•Suitable Nb co-doping causes an improvement of Eu3+ luminescence properties.•Several types of oxygen sensitivity of the Eu3+ luminescence is observed.
ISSN:0254-0584
1879-3312
DOI:10.1016/j.matchemphys.2018.04.090