The influence of morphology and Eu3+ concentration on luminescence and temperature sensing behavior of Ba2MgWO6 double perovskite as a potential optical thermometer

The paper presents the temperature sensing potential of Ba2Mg1-2xEuxLixWO6 as a self-calibrating luminescent thermometer based on the temperature-dependent emission intensity of two independent emission centers. The luminescent thermometer based on the spin-allowed emission of host and the spin-forb...

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Published inJournal of alloys and compounds Vol. 842; p. 155742
Main Authors Stefańska, D., Bondzior, B., Vu, T.H.Q., Miniajluk-Gaweł, N., Dereń, P.J.
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier B.V 25.11.2020
Elsevier BV
Subjects
Ba2MgWO6
Charge transfer
Double perovskites
Emission
Energy transfer
Eu3
Europium
Li
Low temperature
Luminescence
Luminescence thermometer
Metal ions
Morphology
Perovskites
Temperature dependence
Temperature sensor
Temperature sensors
Ba2MgWO6
Temperature sensor
Eu3
Luminescence thermometer
Double perovskites
Li
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Summary:The paper presents the temperature sensing potential of Ba2Mg1-2xEuxLixWO6 as a self-calibrating luminescent thermometer based on the temperature-dependent emission intensity of two independent emission centers. The luminescent thermometer based on the spin-allowed emission of host and the spin-forbidden emission of rare earth ions can be a promising direction for non-contact temperature sensing and a highly interesting extension to this field. The experimental results show that the high probability of the energy transfer from the tungstate group to Eu3+ is the reason why the spin-allowed emission of [WO6]6- group was observed only for the samples with the lowest dopant concentration. The mechanism responsible for the thermal depopulation of 5D0 luminescence of Eu3+ ions is mainly induced by the charge transfer (CT) states of tungstate groups. The study of the temperature sensing showed that the sample exhibits the best temperature sensing ability in the low-temperature region (77–200 K) with the maximum of the relative sensitivity 1.5% K−1 at 120 K and that potentially it can be applied it as a low-temperature sensor. [Display omitted] •Ba2MgWO6:Eu3+, Li+ (BMW) double perovskite was for the first time obtained by mechanochemical method.•BMW is a first luminescence thermometer based on [WO6]6-/Eu3+ (5D0.→7F1) emission.•BMW presents unique temperature sensitivities at low temperature range (below 200 K).•The mechanism of thermal depopulation of 5D0 luminescence of Eu3+ ions and is proposed.•Correlation between energy activation ΔE and temperature sensing range was discussed.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2020.155742