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      Multimodal Non-Contact Luminescence Thermometry with Cr-Doped Oxides

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          Abstract

          Luminescence methods for non-contact temperature monitoring have evolved through improvements of hardware and sensor materials. Future advances in this field rely on the development of multimodal sensing capabilities of temperature probes and extend the temperature range across which they operate. The family of Cr-doped oxides appears particularly promising and we review their luminescence characteristics in light of their application in non-contact measurements of temperature over the 5–300 K range. Multimodal sensing utilizes the intensity ratio of emission lines, their wavelength shift, and the scintillation decay time constant. We carried out systematic studies of the temperature-induced changes in the luminescence of the Cr 3+-doped oxides Al 2O 3, Ga 2O 3, Y 3Al 5O 12, and YAlO 3. The mechanism responsible for the temperature-dependent luminescence characteristic is discussed in terms of relevant models. It is shown that the thermally-induced processes of particle exchange, governing the dynamics of Cr 3+ ion excited state populations, require low activation energy. This then translates into tangible changes of a luminescence parameter with temperature. We compare different schemes of temperature sensing and demonstrate that Ga 2O 3-Cr is a promising material for non-contact measurements at cryogenic temperatures. A temperature resolution better than ±1 K can be achieved by monitoring the luminescence intensity ratio (40–140 K) and decay time constant (80–300 K range).

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          Thermometry at the nanoscale.

          Non-invasive precise thermometers working at the nanoscale with high spatial resolution, where the conventional methods are ineffective, have emerged over the last couple of years as a very active field of research. This has been strongly stimulated by the numerous challenging requests arising from nanotechnology and biomedicine. This critical review offers a general overview of recent examples of luminescent and non-luminescent thermometers working at nanometric scale. Luminescent thermometers encompass organic dyes, QDs and Ln(3+)ions as thermal probes, as well as more complex thermometric systems formed by polymer and organic-inorganic hybrid matrices encapsulating these emitting centres. Non-luminescent thermometers comprise of scanning thermal microscopy, nanolithography thermometry, carbon nanotube thermometry and biomaterials thermometry. Emphasis has been put on ratiometric examples reporting spatial resolution lower than 1 micron, as, for instance, intracellular thermometers based on organic dyes, thermoresponsive polymers, mesoporous silica NPs, QDs, and Ln(3+)-based up-converting NPs and β-diketonate complexes. Finally, we discuss the challenges and opportunities in the development for highly sensitive ratiometric thermometers operating at the physiological temperature range with submicron spatial resolution.
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            Luminescent probes and sensors for temperature.

            Temperature (T) is probably the most fundamental parameter in all kinds of science. Respective sensors are widely used in daily life. Besides conventional thermometers, optical sensors are considered to be attractive alternatives for sensing and on-line monitoring of T. This Review article focuses on all kinds of luminescent probes and sensors for measurement of T, and summarizes the recent progress in their design and application formats. The introduction covers the importance of optical probes for T, the origin of their T-dependent spectra, and the various detection modes. This is followed by a survey on (a) molecular probes, (b) nanomaterials, and (c) bulk materials for sensing T. This section will be completed by a discussion of (d) polymeric matrices for immobilizing T-sensitive probes and (e) an overview of the various application formats of T-sensors. The review ends with a discussion on the prospects, challenges, and new directions in the design of optical T-sensitive probes and sensors.
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              Lanthanide-Based Thermometers: At the Cutting-Edge of Luminescence Thermometry

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                Author and article information

                Journal
                Sensors (Basel)
                Sensors (Basel)
                sensors
                Sensors (Basel, Switzerland)
                MDPI
                1424-8220
                15 September 2020
                September 2020
                : 20
                : 18
                : 5259
                Affiliations
                [1 ]Diamond Light Source, Harwell Campus, Didcot OX11 0DE, UK; armin.wagner@ 123456diamond.ac.uk
                [2 ]Denys Wilkinson Building, Department of Physics, University of Oxford, Oxford OX1 3RH, UK; hans.kraus@ 123456physics.ox.ac.uk
                [3 ]Institute of Physics, Polish Academy of Sciences, Al. Lotników 32/46, 02-668 Warsaw, Poland; zhydach@ 123456ifpan.edu.pl (Y.Z.); tsiumra@ 123456gmail.com (V.T.); suchy@ 123456ifpan.edu.pl (A.S.)
                [4 ]Lviv Polytechnic National University, 12 Bandera, Lviv 79646, Ukraine
                [5 ]Ivan Franko National University of Lviv, Tarnavskogo Str. 107, 79017 Lviv, Ukraine; andriy.luchechko@ 123456lnu.edu.ua
                [6 ]Institute of Physics, University of Bydgoszcz, Weyssenhoffa 11, 85-072 Bydgoszcz, Poland
                Author notes
                Author information
                https://orcid.org/0000-0003-4774-5977
                Article
                sensors-20-05259
                10.3390/s20185259
                7570664
                32942602
                9796c5b4-468a-4b91-9953-8474fb8a8887
                © 2020 by the authors.

                Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license ( http://creativecommons.org/licenses/by/4.0/).

                History
                : 18 August 2020
                : 11 September 2020
                Categories
                Article

                Biomedical engineering
                non-contact luminescence thermometry,luminescence decay thermometry,intensity ratio thermometry,wavelength shift thermometry,cr3+ emission

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