Multimode luminescence thermometry based on emission and excitation spectra

Luminescence thermometers are widely known to provide contactless and noninvasive temperature sensing when traditional thermometers are useless. Their operation principle is based on the monitoring of the chosen temperature dependent luminescence parameter. The vast majority of known luminescence th...

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Bibliographic Details
Published in:Journal of luminescence 2021-03, Vol.231, p.117828, Article 117828
Main Authors: Kolesnikov, Ilya E., Mamonova, Daria V., Kurochkin, Mikhail A., Kolesnikov, Evgenii Yu, Lähderanta, Erkki
Format: Article
Language:English
Subjects:
Luminescence thermometry
Multimode sensing
Single band ratiometric approach
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Summary:Luminescence thermometers are widely known to provide contactless and noninvasive temperature sensing when traditional thermometers are useless. Their operation principle is based on the monitoring of the chosen temperature dependent luminescence parameter. The vast majority of known luminescence thermometers use one parameter to define temperature, while multimode sensors, which could broaden the working range and improve thermometric characteristics, are still rare. We report on YVO4:Er3+ 0.1 at.% sample as a thermal sensor in 299–466 K range with multiple sensing techniques utilized luminescence intensity ratio, spectral line position and bandwidth. These temperature dependent parameters were obtained from both emission and excitation spectra. The relative thermal sensitivity was varied from 0.34 to 2.61% K−1 at room temperature depending on the chosen luminescence parameter. All studied sensing methods provide sub-degree temperature resolution. [Display omitted] •YVO4:Er3+ phosphor was used as contactless luminescence thermometer.•Luminescence intensity ratio, line position and bandwidth were utilized for thermal sensing.•Temperature can be obtained from both emission and excitation spectra.•YVO4:Er3+ relative thermal sensitivity reached 2.61% K−1 at room temperature.•Suggested sensing techniques allow to define local temperature with sub-degree resolution.
ISSN:0022-2313
1872-7883
DOI:10.1016/j.jlumin.2020.117828