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2. Rise and Decay of Photoluminescence in Upconverting Lanthanide-Doped Nanocrystals

Author

Vonk, Sander J. W., Maris, J. J. Erik, Dekker, Ayla J. H., de Wit, Jur W., van Swieten, Thomas P., Cocina, Ario, and Rabouw, Freddy T.

Abstract

Nanocrystals (NCs) doped with lanthanides are capable of efficient photon upconversion, i.e., absorbing long-wavelength light and emitting shorter-wavelength light. The internal processes that enable upconversion are a complex network of electronic transitions within and energy transfer between dopant centers. In this work, we study the rise and decay dynamics of upconversion emission from β-NaYF4NCs codoped with Er3+and Yb3+. The rise dynamics of the red and green upconverted emissions are nonlinear, reflecting the nonlinear nature of upconversion and revealing the mechanisms that populate the emitting states. The excited-state decay dynamics are nonexponential. We unravel the underlying decay pathways using photonic experiments. These reveal the contributions of different upconversion pathways visually, as each pathway exhibits a distinct response to systematic variation of the local density of optical states. Moreover, the effect of the local density of optical states on core-only NCs is qualitatively different from core–shell NCs. This is due to the different balance between feeding and decay of the electronic levels that produce upconverted emission. The understanding of the upconversion dynamics provided here could lead to better imaging and sensing methods relying on upconversion lifetimes or guide the rational optimization of the dopant concentrations for brighter upconversion.

Published
2024
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3. Mapping Temperature Heterogeneities during Catalytic CO2 Methanation with Operando Luminescence Thermometry

Author

Jacobs, Thimo S., primary, van Swieten, Thomas P., additional, Vonk, Sander J. W., additional, Bosman, Isa P., additional, Melcherts, Angela E. M., additional, Janssen, Bas C., additional, Janssens, Joris C. L., additional, Monai, Matteo, additional, Meijerink, Andries, additional, Rabouw, Freddy T., additional, van der Stam, Ward, additional, and Weckhuysen, Bert M., additional

Published
2023
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6. Photonic Artifacts in Ratiometric Luminescence Nanothermometry

Author

Vonk, Sander J.W., van Swieten, Thomas P., Cocina, Ario, Rabouw, Freddy T., Vonk, Sander J.W., van Swieten, Thomas P., Cocina, Ario, and Rabouw, Freddy T.

Abstract

Ongoing developments in science and technology require temperature measurements at increasingly higher spatial resolutions. Nanocrystals with temperature-sensitive luminescence are a popular thermometer for these applications offering high precision and remote read-out. Here, we demonstrate that ratiometric luminescence thermometry experiments may suffer from systematic errors in nanostructured environments. We place lanthanide-based luminescent nanothermometers at controlled distances of up to 600 nm from a Au surface. Although this geometry supports no absorption or scattering resonances, distortion of the emission spectra of the thermometers due to the modified density of optical states results in temperature read-out errors of up to 250 K. Our simple analytical model explains the effects of thermometer emission frequencies, experimental equipment, and sample properties on the magnitude of the errors. We discuss the relevance of our findings in several experimental scenarios. Such errors do not always occur, but they are expected in measurements near reflecting interfaces or scattering objects.

Published
2023

7. Increasing the Power: Absorption Bleach, Thermal Quenching, and Auger Quenching of the Red-Emitting Phosphor K2TiF6:Mn4+

Author

de Wit, Jur W., van Swieten, Thomas P., van de Haar, Marie Anne, Meijerink, Andries, Rabouw, Freddy T., de Wit, Jur W., van Swieten, Thomas P., van de Haar, Marie Anne, Meijerink, Andries, and Rabouw, Freddy T.

Abstract

Mn4+-doped fluorides are popular phosphors for warm-white lighting, converting blue light from light-emitting diodes (LEDs) into red light. However, they suffer from droop, that is, decreasing performance at increasing power, limiting their applicability for high-power applications. Previous studies highlight different causes of droop. Here, a unified picture of droop of Mn4+-doped K2TiF6, accounting for all previously proposed mechanisms, is provided. Combining continuous-wave and pulsed experiments on samples of different Mn4+ content with kinetic Monte Carlo modeling, the contributions of absorption bleach, thermal quenching, and Auger quenching at different excitation densities, are quantified. This work contributes to understanding the fundamental limitations of these materials and may inspire strategies to make Mn4+-doped fluorides more efficient in high-power applications.

Published
2023

8. Probing nearby molecular vibrations with lanthanide-doped nanocrystals

Author

Mangnus, Mark J.J., Benning, Vincent R.M., Baumgartner, Bettina, Prins, P. Tim, van Swieten, Thomas P., Dekker, Ayla J.H., van Blaaderen, Alfons, Weckhuysen, Bert M., Meijerink, Andries, Rabouw, Freddy T., Mangnus, Mark J.J., Benning, Vincent R.M., Baumgartner, Bettina, Prins, P. Tim, van Swieten, Thomas P., Dekker, Ayla J.H., van Blaaderen, Alfons, Weckhuysen, Bert M., Meijerink, Andries, and Rabouw, Freddy T.

Abstract

The photoluminescence (PL) of lanthanide-doped nanocrystals can be quenched by energy transfer to vibrations of molecules located within a few nanometers from the dopants. Such short-range electronic-to-vibrational energy transfer (EVET) is often undesired as it reduces the photoluminescence efficiency. On the other hand, EVET may be exploited to extract information about molecular vibrations in the local environment of the nanocrystals. Here, we investigate the influence of solvent and gas environments on the PL properties of NaYF4:Er3+,Yb3+ upconversion nanocrystals. We relate changes in the PL spectrum and excited-state lifetimes in different solvents and their deuterated analogues to quenching of specific lanthanide levels by EVET to molecular vibrations. Similar but weaker changes are induced when we expose a film of nanocrystals to a gas environment with different amounts of H2O or D2O vapor. Quenching of green- and red-emitting levels of Er3+ can be explained in terms of EVET-mediated quenching that involves molecular vibrations with energies resonant with the gap between the energy levels of the lanthanide. Quenching of the near-infrared-emitting level is more complex and may involve EVET to combination-vibrations or defect-mediated quenching. EVET-mediated quenching holds promise as a mechanism to probe the local chemical environment—both for nanocrystals dispersed in a liquid and for nanocrystals exposed to gaseous molecules that adsorb onto the nanocrystal surface.

Published
2023

9. Mapping Temperature Heterogeneities during Catalytic CO2 Methanation with Operando Luminescence Thermometry

Author

Jacobs, Thimo S, van Swieten, Thomas P, Vonk, Sander J W, Bosman, Isa P, Melcherts, Angela E M, Janssen, Bas C, Janssens, Joris C L, Monai, Matteo, Meijerink, Andries, Rabouw, Freddy T, van der Stam, Ward, Weckhuysen, Bert M, Jacobs, Thimo S, van Swieten, Thomas P, Vonk, Sander J W, Bosman, Isa P, Melcherts, Angela E M, Janssen, Bas C, Janssens, Joris C L, Monai, Matteo, Meijerink, Andries, Rabouw, Freddy T, van der Stam, Ward, and Weckhuysen, Bert M

Abstract

Controlling and understanding reaction temperature variations in catalytic processes are crucial for assessing the performance of a catalyst material. Local temperature measurements are challenging, however. Luminescence thermometry is a promising remote-sensing tool, but it is cross-sensitive to the optical properties of a sample and other external parameters. In this work, we measure spatial variations in the local temperature on the micrometer length scale during carbon dioxide (CO 2) methanation over a TiO 2-supported Ni catalyst and link them to variations in catalytic performance. We extract local temperatures from the temperature-dependent emission of Y 2O 3:Nd 3+ particles, which are mixed with the CO 2 methanation catalyst. Scanning, where a near-infrared laser locally excites the emitting Nd 3+ ions, produces a temperature map with a micrometer pixel size. We first designed the Y 2O 3:Nd 3+ particles for optimal temperature precision and characterized cross-sensitivity of the measured signal to parameters other than temperature, such as light absorption by the blackened sample due to coke deposition at elevated temperatures. Introducing reaction gases causes a local temperature increase of the catalyst of on average 6-25 K, increasing with the reactor set temperature in the range of 550-640 K. Pixel-to-pixel variations in the temperature increase show a standard deviation of up to 1.5 K, which are attributed to local variations in the catalytic reaction rate. Mapping and understanding such temperature variations are crucial for the optimization of overall catalyst performance on the nano- and macroscopic scale.

Published
2023

10. Increasing the Power: Absorption Bleach, Thermal Quenching, and Auger Quenching of the Red-Emitting Phosphor K2TiF6:Mn4+

Author

Sub Condensed Matter and Interfaces, Sub Soft Condensed Matter, Sub Organic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, de Wit, Jur W., van Swieten, Thomas P., van de Haar, Marie Anne, Meijerink, Andries, Rabouw, Freddy T., Sub Condensed Matter and Interfaces, Sub Soft Condensed Matter, Sub Organic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, de Wit, Jur W., van Swieten, Thomas P., van de Haar, Marie Anne, Meijerink, Andries, and Rabouw, Freddy T.

Published
2023

11. Photonic Artifacts in Ratiometric Luminescence Nanothermometry

Author

Sub Organic Chemistry and Catalysis, Sub Soft Condensed Matter, Sub Condensed Matter and Interfaces, Sub Inorganic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, Vonk, Sander J.W., van Swieten, Thomas P., Cocina, Ario, Rabouw, Freddy T., Sub Organic Chemistry and Catalysis, Sub Soft Condensed Matter, Sub Condensed Matter and Interfaces, Sub Inorganic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, Vonk, Sander J.W., van Swieten, Thomas P., Cocina, Ario, and Rabouw, Freddy T.

Published
2023

12. Mapping Temperature Heterogeneities during Catalytic CO2 Methanation with Operando Luminescence Thermometry

Author

Inorganic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, Sub Inorganic Chemistry and Catalysis, Sub Condensed Matter and Interfaces, Sub Soft Condensed Matter, Condensed Matter and Interfaces, Jacobs, Thimo S, van Swieten, Thomas P, Vonk, Sander J W, Bosman, Isa P, Melcherts, Angela E M, Janssen, Bas C, Janssens, Joris C L, Monai, Matteo, Meijerink, Andries, Rabouw, Freddy T, van der Stam, Ward, Weckhuysen, Bert M, Inorganic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, Sub Inorganic Chemistry and Catalysis, Sub Condensed Matter and Interfaces, Sub Soft Condensed Matter, Condensed Matter and Interfaces, Jacobs, Thimo S, van Swieten, Thomas P, Vonk, Sander J W, Bosman, Isa P, Melcherts, Angela E M, Janssen, Bas C, Janssens, Joris C L, Monai, Matteo, Meijerink, Andries, Rabouw, Freddy T, van der Stam, Ward, and Weckhuysen, Bert M

Published
2023

13. The Formation of NaYF4: Er3+, Yb3+ Nanocrystals Studied by In Situ X-ray Scattering: Phase Transition and Size Focusing

Author

Physical and Colloid Chemistry, Sub Inorganic Chemistry and Catalysis, Sub Condensed Matter and Interfaces, Sub Soft Condensed Matter, Sub Physical and Colloid Chemistry, Inorganic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, Condensed Matter and Interfaces, Prins, P. Tim, van der Bok, Johanna C., van Swieten, Thomas P., Hinterding, Stijn O.M., Smith, Andy J., Petukhov, Andrei V., Meijerink, Andries, Rabouw, Freddy T., Physical and Colloid Chemistry, Sub Inorganic Chemistry and Catalysis, Sub Condensed Matter and Interfaces, Sub Soft Condensed Matter, Sub Physical and Colloid Chemistry, Inorganic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, Condensed Matter and Interfaces, Prins, P. Tim, van der Bok, Johanna C., van Swieten, Thomas P., Hinterding, Stijn O.M., Smith, Andy J., Petukhov, Andrei V., Meijerink, Andries, and Rabouw, Freddy T.

Published
2023

14. Probing nearby molecular vibrations with lanthanide-doped nanocrystals

Author

Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Sub Condensed Matter and Interfaces, Afd Soft Condensed Matter and Biophysics, Inorganic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, Condensed Matter and Interfaces, Mangnus, Mark J.J., Benning, Vincent R.M., Baumgartner, Bettina, Prins, P. Tim, van Swieten, Thomas P., Dekker, Ayla J.H., van Blaaderen, Alfons, Weckhuysen, Bert M., Meijerink, Andries, Rabouw, Freddy T., Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Sub Condensed Matter and Interfaces, Afd Soft Condensed Matter and Biophysics, Inorganic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, Condensed Matter and Interfaces, Mangnus, Mark J.J., Benning, Vincent R.M., Baumgartner, Bettina, Prins, P. Tim, van Swieten, Thomas P., Dekker, Ayla J.H., van Blaaderen, Alfons, Weckhuysen, Bert M., Meijerink, Andries, and Rabouw, Freddy T.

Published
2023

15. Impact of Noise and Background on Measurement Uncertainties in Luminescence Thermometry

Author

Van Swieten, Thomas P., Meijerink, Andries, Rabouw, Freddy T., Sub Condensed Matter and Interfaces, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Soft Condensed Matter and Biophysics, Sub Condensed Matter and Interfaces, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, and Soft Condensed Matter and Biophysics

Subjects
background, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, temperature uncertainty, statistics, Atomic and Molecular Physics, Electronic, (EM)CCD, Optical and Magnetic Materials, and Optics, Electrical and Electronic Engineering, absorption cross section, luminescence thermometry, Biotechnology
Abstract

Materials with temperature-dependent luminescence can be used as local thermometers when incorporated in, for example, a biological environment or chemical reactor. Researchers have continuously developed new materials aiming for the highest sensitivity of luminescence to temperature. Although the comparison of luminescent materials based on their temperature sensitivity is convenient, this parameter gives an incomplete description of the potential performance of the materials in applications. Here, we demonstrate how the precision of a temperature measurement with luminescent nanocrystals depends not only on the temperature sensitivity of the nanocrystals but also on their luminescence strength compared to measurement noise and background signal. After first determining the noise characteristics of our instrumentation, we show how the uncertainty of a temperature measurement can be predicted quantitatively. Our predictions match the temperature uncertainties that we extract from repeated measurements, over a wide temperature range (303-473 K), for different CCD readout settings, and for different background levels. The work presented here is the first study that incorporates all of these practical issues to accurately calculate the uncertainty of luminescent nanothermometers. This method will be important for the optimization and development of luminescent nanothermometers.

Published
2022
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17. Bifunctional Europium for Operando Catalyst Thermometry in an Exothermic Chemical Reaction

Author

Terlingen, Bas, Arens, Tjom, van Swieten, Thomas P, Rabouw, Freddy T, Prins, Tim, de Beer, Michiel M, Meijerink, Andries, Ahr, Mathieu, Hutter, Eline M, van Lare, Coert, Weckhuysen, Bert Marc, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Sub Condensed Matter and Interfaces, Faculteit Betawetenschappen, Inorganic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, and Condensed Matter and Interfaces

Subjects
Europium, Heterogeneous Catalysis, Chemistry(all), Operando Methods, General Chemistry, General Medicine, Thermometry, Methane, Catalysis
Abstract

Often the reactor or the reaction medium temperature is reported in the field of heterogeneous catalysis, even though it could vary significantly from the reactive catalyst temperature. The influence of the catalyst temperature on the catalytic performance and vice versa is therefore not always accurately known. We here apply EuOCl as both solid catalyst and thermometer, allowing for operando temperature determination. The interplay between reaction conditions and the catalyst temperature dynamics is studied. A maximum temperature difference between the catalyst and oven of +16 °C was observed due to the exothermicity of the methane oxychlorination reaction. Heat dissipation by radiation appears dominating compared to convection in this set-up, explaining the observed uniform catalyst bed temperature. Application of operando catalyst thermometry could provide a deeper mechanistic understanding of catalyst performances and allow for safer process operation in chemical industries.

Published
2022

20. Mapping Elevated Temperatures with a Micrometer Resolution Using the Luminescence of Chemically Stable Upconversion Nanoparticles

Author

Van Swieten, Thomas P., Van Omme, Tijn, Van Den Heuvel, Dave J., Vonk, Sander J.W., Spruit, Ronald G., Meirer, Florian, Garza, H. Hugo Pérez, Weckhuysen, Bert M., Meijerink, Andries, Rabouw, Freddy T., Geitenbeek, Robin G., Sub Condensed Matter and Interfaces, Sub Molecular Biophysics, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Faculteit Betawetenschappen, Sub Algemeen Scheikunde, Soft Condensed Matter and Biophysics, Sub Condensed Matter and Interfaces, Sub Molecular Biophysics, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Faculteit Betawetenschappen, Sub Algemeen Scheikunde, and Soft Condensed Matter and Biophysics

Subjects
Materials science, business.industry, Scattering, spectral artifacts, Resolution (electron density), photonics, Nanoparticle, Article, Micrometre, nanothermometry, temperature mapping, Materials Science(all), Nanoelectronics, Microscopy, luminescence, microscopy, Optoelectronics, General Materials Science, business, Luminescence, Image resolution
Abstract

The temperature-sensitive luminescence of nanoparticles enables their application as remote thermometers. The size of these nanothermometers makes them ideal to map temperatures with a high spatial resolution. However, high spatial resolution mapping of temperatures >373 K has remained challenging. Here, we realize nanothermometry with high spatial resolutions at elevated temperatures using chemically stable upconversion nanoparticles and confocal microscopy. We test this method on a microelectromechanical heater and study the temperature homogeneity. Our experiments reveal distortions in the luminescence spectra that are intrinsic to high-resolution measurements of samples with nanoscale photonic inhomogeneities. In particular, the spectra are affected by the high-power excitation as well as by scattering and reflection of the emitted light. The latter effect has an increasing impact at elevated temperatures. We present a procedure to correct these distortions. As a result, we extend the range of high-resolution nanothermometry beyond 500 K with a precision of 1–4 K. This work will improve the accuracy of nanothermometry not only in micro- and nanoelectronics but also in other fields with photonically inhomogeneous substrates.

Published
2021
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21. The Formation of NaYF4 : Er3+, Yb3+ Nanocrystals Studied by In Situ X‐ray Scattering: Phase Transition and Size Focusing.

Author

Prins, P. Tim, van der Bok, Johanna C., van Swieten, Thomas P., Hinterding, Stijn O. M., Smith, Andy J., Petukhov, Andrei V., Meijerink, Andries, and Rabouw, Freddy T.

Subjects
PHASE transitions, X-ray scattering, SMALL-angle X-ray scattering, NANOCRYSTALS, PARTICLE size distribution, YTTERBIUM
Abstract

β‐NaYF4 nanocrystals are a popular class of optical materials. They can be doped with optically active lanthanide ions and shaped into core‐multi‐shell geometries with controlled dopant distributions. Here, we follow the synthesis of β‐NaYF4 nanocrystals from α‐NaYF4 precursor particles using in situ small‐angle and wide‐angle X‐ray scattering and ex situ electron microscopy. We observe an evolution from a unimodal particle size distribution to bimodal, and eventually back to unimodal. The final size distribution is narrower in absolute numbers than the initial distribution. These peculiar growth dynamics happen in large part before the α‐to‐β phase transformation. We propose that the splitting of the size distribution is caused by variations in the reactivity of α‐NaYF4 precursor particles, potentially due to inter‐particle differences in stoichiometry. Rate equation modeling confirms that a continuous distribution of reactivities can result in the observed particle growth dynamics. [ABSTRACT FROM AUTHOR]

Published
2023
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22. Beyond the Energy Gap Law: The Influence of Selection Rules and Host Compound Effects on Nonradiative Transition Rates in Boltzmann Thermometers

Author

Netzsch, Philip, Hämmer, Matthias, Turgunbajew, Erich, van Swieten, Thomas P., Meijerink, Andries, Höppe, Henning A., Suta, Markus, Sub Condensed Matter and Interfaces, Condensed Matter and Interfaces, University of St Andrews. School of Chemistry, Sub Condensed Matter and Interfaces, and Condensed Matter and Interfaces

Subjects
MCC, Gd, borosulfates, Structure–property relationship, NDAS, nonradiative transitions, Luminescence thermometry, QD Chemistry, structure–property relationship, Gd3+, Atomic and Molecular Physics, and Optics, borates, Electronic, Optical and Magnetic Materials, Borosulfates, Atomic and Molecular Physics, ddc:540, Borates, Electronic, QD, Optical and Magnetic Materials, Nonradiative transitions, and Optics, luminescence thermometry
Abstract

P.N. and M.H. contributed equally to this work. H.A.H., P.N., M.H., and E.T. thank the Deutsche Forschungsgemeinschaft (DFG) for generous support (Project HO 4503/5-1). Open access funding enabled and organized by Projekt DEAL. Apart from the energy gap law, control parameters over nonradiative transitions are so far only scarcely regarded. In this work, the impact of both covalence of the lanthanoid–ligand bond and varying bond distance on the magnitude of the intrinsic nonradiative decay rate between the excited 6P5/2 and 6P7/2 spin–orbit levels of Gd3+ is investigated in the chemically related compounds Y2[B2(SO4)6] and LaBO3. Analysis of the temperature-dependent luminescence spectra reveals that the intrinsic nonradiative transition rates between the excited 6PJ ( J = 5/2, 7/2) levels are of the order of only 10 ms−1 (Y2[B2(SO4)6]:Gd3+: 8.9 ms−1; LaBO3:Gd3+: 10.5 ms−1) and differ due to the different degree of covalence of the Gd—O bonds in the two compounds. Comparison to the established luminescent Boltzmann thermometer Er3+ reveals, however, that the nonradiative transition rates between the excited levels of Gd3+ are over three orders of magnitude slower despite a similar energy gap and the presence of a single resonant phonon mode. This hints to a fundamental magnetic dipolar character of the nonradiative coupling in Gd3+. These findings can pave a way to control nonradiative transition rates and how to tune the dynamic range of luminescent Boltzmann thermometers. Publisher PDF

Published
2022

23. Beyond the Energy Gap Law: The Influence of Selection Rules and Host Compound Effects on Nonradiative Transition Rates in Boltzmann Thermometers

Author

Sub Condensed Matter and Interfaces, Condensed Matter and Interfaces, Netzsch, Philip, Hämmer, Matthias, Turgunbajew, Erich, van Swieten, Thomas P., Meijerink, Andries, Höppe, Henning A., Suta, Markus, Sub Condensed Matter and Interfaces, Condensed Matter and Interfaces, Netzsch, Philip, Hämmer, Matthias, Turgunbajew, Erich, van Swieten, Thomas P., Meijerink, Andries, Höppe, Henning A., and Suta, Markus

Published
2022

24. Impact of Noise and Background on Measurement Uncertainties in Luminescence Thermometry

Author

Sub Condensed Matter and Interfaces, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Soft Condensed Matter and Biophysics, Van Swieten, Thomas P., Meijerink, Andries, Rabouw, Freddy T., Sub Condensed Matter and Interfaces, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Soft Condensed Matter and Biophysics, Van Swieten, Thomas P., Meijerink, Andries, and Rabouw, Freddy T.

Published
2022

25. Bifunctional Europium for Operando Catalyst Thermometry in an Exothermic Chemical Reaction

Author

Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Sub Condensed Matter and Interfaces, Faculteit Betawetenschappen, Inorganic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, Condensed Matter and Interfaces, Terlingen, Bas, Arens, Tjom, van Swieten, Thomas P, Rabouw, Freddy T, Prins, Tim, de Beer, Michiel M, Meijerink, Andries, Ahr, Mathieu, Hutter, Eline M, van Lare, Coert, Weckhuysen, Bert Marc, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Sub Condensed Matter and Interfaces, Faculteit Betawetenschappen, Inorganic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, Condensed Matter and Interfaces, Terlingen, Bas, Arens, Tjom, van Swieten, Thomas P, Rabouw, Freddy T, Prins, Tim, de Beer, Michiel M, Meijerink, Andries, Ahr, Mathieu, Hutter, Eline M, van Lare, Coert, and Weckhuysen, Bert Marc

Published
2022

26. Mapping Temperature Heterogeneities during Catalytic CO2Methanation with OperandoLuminescence Thermometry

Author

Jacobs, Thimo S., van Swieten, Thomas P., Vonk, Sander J. W., Bosman, Isa P., Melcherts, Angela E. M., Janssen, Bas C., Janssens, Joris C. L., Monai, Matteo, Meijerink, Andries, Rabouw, Freddy T., van der Stam, Ward, and Weckhuysen, Bert M.

Abstract

Controlling and understanding reaction temperature variations in catalytic processes are crucial for assessing the performance of a catalyst material. Local temperature measurements are challenging, however. Luminescence thermometry is a promising remote-sensing tool, but it is cross-sensitive to the optical properties of a sample and other external parameters. In this work, we measure spatial variations in the local temperature on the micrometer length scale during carbon dioxide (CO2) methanation over a TiO2-supported Ni catalyst and link them to variations in catalytic performance. We extract local temperatures from the temperature-dependent emission of Y2O3:Nd3+particles, which are mixed with the CO2methanation catalyst. Scanning, where a near-infrared laser locally excites the emitting Nd3+ions, produces a temperature map with a micrometer pixel size. We first designed the Y2O3:Nd3+particles for optimal temperature precision and characterized cross-sensitivity of the measured signal to parameters other than temperature, such as light absorption by the blackened sample due to coke deposition at elevated temperatures. Introducing reaction gases causes a local temperature increase of the catalyst of on average 6–25 K, increasing with the reactor set temperature in the range of 550–640 K. Pixel-to-pixel variations in the temperature increase show a standard deviation of up to 1.5 K, which are attributed to local variations in the catalytic reaction rate. Mapping and understanding such temperature variations are crucial for the optimization of overall catalyst performance on the nano- and macroscopic scale.

Published
2023
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27. Increasing the Power: Absorption Bleach, Thermal Quenching, and Auger Quenching of the Red‐Emitting Phosphor K2TiF6:Mn4+.

Author

de Wit, Jur W., van Swieten, Thomas P., van de Haar, Marie Anne, Meijerink, Andries, and Rabouw, Freddy T.

Subjects
*PHOSPHORS, *AUGERS, *ABSORPTION, *LIGHT emitting diodes, *BLUE light, *TERBIUM
Abstract

Mn4+‐doped fluorides are popular phosphors for warm‐white lighting, converting blue light from light‐emitting diodes (LEDs) into red light. However, they suffer from droop, that is, decreasing performance at increasing power, limiting their applicability for high‐power applications. Previous studies highlight different causes of droop. Here, a unified picture of droop of Mn4+‐doped K2TiF6, accounting for all previously proposed mechanisms, is provided. Combining continuous‐wave and pulsed experiments on samples of different Mn4+ content with kinetic Monte Carlo modeling, the contributions of absorption bleach, thermal quenching, and Auger quenching at different excitation densities, are quantified. This work contributes to understanding the fundamental limitations of these materials and may inspire strategies to make Mn4+‐doped fluorides more efficient in high‐power applications. [ABSTRACT FROM AUTHOR]

Published
2023
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28. Increasing the Power: Absorption Bleach, Thermal Quenching, and Auger Quenching of the Red‐Emitting Phosphor K2TiF6:Mn4+.

Author

de Wit, Jur W., van Swieten, Thomas P., van de Haar, Marie Anne, Meijerink, Andries, and Rabouw, Freddy T.

Subjects
PHOSPHORS, AUGERS, ABSORPTION, LIGHT emitting diodes, BLUE light, TERBIUM
Abstract

Mn4+‐doped fluorides are popular phosphors for warm‐white lighting, converting blue light from light‐emitting diodes (LEDs) into red light. However, they suffer from droop, that is, decreasing performance at increasing power, limiting their applicability for high‐power applications. Previous studies highlight different causes of droop. Here, a unified picture of droop of Mn4+‐doped K2TiF6, accounting for all previously proposed mechanisms, is provided. Combining continuous‐wave and pulsed experiments on samples of different Mn4+ content with kinetic Monte Carlo modeling, the contributions of absorption bleach, thermal quenching, and Auger quenching at different excitation densities, are quantified. This work contributes to understanding the fundamental limitations of these materials and may inspire strategies to make Mn4+‐doped fluorides more efficient in high‐power applications. [ABSTRACT FROM AUTHOR]

Published
2023
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29. High temperature (nano)thermometers based on LiLuF4:Er3+,Yb3+nano- And microcrystals. Confounded results for core-shell nanocrystals

Author

Kaczmarek, Anna M., Suta, Markus, Rijckaert, Hannes, van Swieten, Thomas P., Van Driessche, Isabel, Kaczmarek, Mariusz K., Meijerink, Andries, Sub Condensed Matter and Interfaces, and Condensed Matter and Interfaces

Abstract

Recent technological developments require knowledge of temperature down to the micro- or even nano-scale. Lanthanide-doped nanoparticles became a popular tool to achieve this. Their temperature sensitive luminescence enables their application as remote thermometers and for mapping temperature profiles with high spatial resolution. Applicability of luminescence thermometry is, however, often limited at high temperatures. In nanoelectronics or chemical reactors, high temperatures above 500 K are common and new approaches for accurate high temperature sensing need to be developed. In this work, we report three different shapes of upconverting LiLuF4:2% Er3+,18% Yb3+nanocrystals both with and without shells and study the influence of the shell on the thermometric properties. We observed peculiar behavior of the core-shell particles suggesting the presence of the dopants within the protective and ‘undoped’ shells. Coating the nanoparticles with a silica layer extends the operational temperature range. In an upconversion (UC) Yb3+-Er3+system temperature sensing relies on thermal coupling between the4S3/2and2H11/2energy levels. At sufficiently high temperatures (>550 K), we observe additional thermal coupling involving the higher4F7/2energy levels. The larger energy gap allows to increase the relative sensitivity at elevated temperatures and to sustain a high temperature precision over a wider temperature range than for a two-level Boltzmann thermometer. The thermal coupling between the4S3/2and2H11/2energy levels is used for lower temperature sensing (550 K).

Published
2021

30. A Ho3+-Based Luminescent Thermometer for Sensitive Sensing over a Wide Temperature Range

Author

van Swieten, Thomas P., Yu, Dechao, Yu, Ting, Vonk, Sander J.W., Suta, Markus, Zhang, Qinyuan, Meijerink, Andries, Rabouw, Freddy T., Sub Condensed Matter and Interfaces, Sub Soft Condensed Matter, Sub Inorganic Chemistry and Catalysis, Condensed Matter and Interfaces, Inorganic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, Sub Condensed Matter and Interfaces, Sub Soft Condensed Matter, Sub Inorganic Chemistry and Catalysis, Condensed Matter and Interfaces, Inorganic Chemistry and Catalysis, and Soft Condensed Matter and Biophysics

Subjects
Materials science, business.industry, cross-relaxation, chemistry.chemical_element, lanthanide luminescence, Atmospheric temperature range, Cross relaxation, luminescence thermometry, remote thermometry, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, chemistry, Atomic and Molecular Physics, Thermometer, Electronic, remote thermometry, Optoelectronics, holmium, Optical and Magnetic Materials, and Optics, Luminescence, business, Holmium, luminescence thermometry
Abstract

Luminescence thermometry is used in a variety of research fields for noninvasive temperature sensing. Lanthanide‐doped micro‐/nanocrystals are exceptionally suitable for this. The popular concept of luminescence‐intensity‐ratio thermometry is based on emission from thermally coupled levels in a single lanthanide ion, following Boltzmann's law. These thermometers can measure temperature with low uncertainty, but only in a limited temperature range. In this work, a Ho3+‐based thermometer is presented and quantitatively modeled with sustained low temperature uncertainty from room temperature up to 873 K. The thermometer shows bright green and red luminescence with a strong and opposite dependence on temperature and Ho3+ concentration. This is the result of temperature‐dependent competition between multi‐phonon relaxation and energy transfer, feeding the green‐ and red‐emitting levels, respectively, following excitation with blue light. This simple and quantitative model of this competition predicts the output spectrum over a wide range of temperatures (300–873 K) and Ho3+ concentrations (0.1–30%). The optimum Ho3+ concentration can thus be determined for reliable measurements over any temperature range of interest. Quantitative modeling as presented here is crucial to optimally benefit from the potential of energy‐transfer thermometers to achieve low measurement uncertainties over a wide temperature range.

Published
2021

31. Mapping Elevated Temperatures with a Micrometer Resolution Using the Luminescence of Chemically Stable Upconversion Nanoparticles

Author

Sub Condensed Matter and Interfaces, Sub Molecular Biophysics, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Faculteit Betawetenschappen, Sub Algemeen Scheikunde, Soft Condensed Matter and Biophysics, Van Swieten, Thomas P., Van Omme, Tijn, Van Den Heuvel, Dave J., Vonk, Sander J.W., Spruit, Ronald G., Meirer, Florian, Garza, H. Hugo Pérez, Weckhuysen, Bert M., Meijerink, Andries, Rabouw, Freddy T., Geitenbeek, Robin G., Sub Condensed Matter and Interfaces, Sub Molecular Biophysics, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Faculteit Betawetenschappen, Sub Algemeen Scheikunde, Soft Condensed Matter and Biophysics, Van Swieten, Thomas P., Van Omme, Tijn, Van Den Heuvel, Dave J., Vonk, Sander J.W., Spruit, Ronald G., Meirer, Florian, Garza, H. Hugo Pérez, Weckhuysen, Bert M., Meijerink, Andries, Rabouw, Freddy T., and Geitenbeek, Robin G.

Published
2021

32. A Ho3+-Based Luminescent Thermometer for Sensitive Sensing over a Wide Temperature Range

Author

Sub Condensed Matter and Interfaces, Sub Soft Condensed Matter, Sub Inorganic Chemistry and Catalysis, Condensed Matter and Interfaces, Inorganic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, van Swieten, Thomas P., Yu, Dechao, Yu, Ting, Vonk, Sander J.W., Suta, Markus, Zhang, Qinyuan, Meijerink, Andries, Rabouw, Freddy T., Sub Condensed Matter and Interfaces, Sub Soft Condensed Matter, Sub Inorganic Chemistry and Catalysis, Condensed Matter and Interfaces, Inorganic Chemistry and Catalysis, Soft Condensed Matter and Biophysics, van Swieten, Thomas P., Yu, Dechao, Yu, Ting, Vonk, Sander J.W., Suta, Markus, Zhang, Qinyuan, Meijerink, Andries, and Rabouw, Freddy T.

Published
2021

33. High temperature (nano)thermometers based on LiLuF4:Er3+,Yb3+nano- And microcrystals. Confounded results for core-shell nanocrystals

Author

Sub Condensed Matter and Interfaces, Condensed Matter and Interfaces, Kaczmarek, Anna M., Suta, Markus, Rijckaert, Hannes, van Swieten, Thomas P., Van Driessche, Isabel, Kaczmarek, Mariusz K., Meijerink, Andries, Sub Condensed Matter and Interfaces, Condensed Matter and Interfaces, Kaczmarek, Anna M., Suta, Markus, Rijckaert, Hannes, van Swieten, Thomas P., Van Driessche, Isabel, Kaczmarek, Mariusz K., and Meijerink, Andries

Published
2021

36. Extending Surface-Enhanced Raman Spectroscopy to Liquids Using Shell-Isolated Plasmonic Superstructures

Author

Wondergem, Caterina S, van Swieten, Thomas P, Geitenbeek, Robin G, Erné, Ben H, Weckhuysen, Bert M, Inorganic Chemistry and Catalysis, Sub Inorganic Chemistry and Catalysis, Sub Physical and Colloid Chemistry, and Physical and Colloid Chemistry

Subjects
Plasmonic nanoparticles, Aqueous solution, 010405 organic chemistry, business.industry, Organic Chemistry, Shell (structure), General Chemistry, Surface-enhanced Raman spectroscopy, 010402 general chemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, Rhodamine 6G, chemistry.chemical_compound, symbols.namesake, chemistry, symbols, Optoelectronics, business, Raman spectroscopy, Plasmon
Abstract

Invited for the cover of this issue is the group of Bert M. Weckhuysen at Utrecht University. The image on the cover shows SHIPS, shell-isolated plasmonic superstructures, detecting the presence of picomoles Rhodamine 6G in an aqueous solution using shell-isolated nanoparticle-enhanced Raman spectroscopy (SHINERS). Read the full text of the article at 10.1002/chem.2019032004.

Published
2019

37. Trapping and Detrapping in Colloidal Perovskite Nanoplatelets: Elucidation and Prevention of Nonradiative Processes through Chemical Treatment

Author

Vonk, Sander J.W. (author), Fridriksson, M.B. (author), Hinterding, Stijn O.M. (author), Mangnus, Mark J.J. (author), Van Swieten, Thomas P. (author), Grozema, F.C. (author), Rabouw, Freddy T. (author), van der Stam, W. (author), Vonk, Sander J.W. (author), Fridriksson, M.B. (author), Hinterding, Stijn O.M. (author), Mangnus, Mark J.J. (author), Van Swieten, Thomas P. (author), Grozema, F.C. (author), Rabouw, Freddy T. (author), and van der Stam, W. (author)

Abstract

Metal-halide perovskite nanocrystals show promise as the future active material in photovoltaics, lighting, and other optoelectronic applications. The appeal of these materials is largely due to the robustness of the optoelectronic properties to structural defects. The photoluminescence quantum yield (PLQY) of most types of perovskite nanocrystals is nevertheless below unity, evidencing the existence of nonradiative charge-carrier decay channels. In this work, we experimentally elucidate the nonradiative pathways in CsPbBr3 nanoplatelets, before and after chemical treatment with PbBr2 that improves the PLQY. A combination of picosecond streak camera and nanosecond time-correlated single-photon counting measurements is used to probe the excited-state dynamics over 6 orders of magnitude in time. We find that up to 40% of the nanoplatelets from a synthesis batch are entirely nonfluorescent and cannot be turned fluorescent through chemical treatment. The other nanoplatelets show fluorescence, but charge-carrier trapping leads to losses that are prevented by chemical treatment. Interestingly, even without chemical treatment, some losses due to trapping are mitigated because trapped carriers spontaneously detrap on nanosecond-to-microsecond timescales. Our analysis shows that multiple nonradiative pathways are active in perovskite nanoplatelets, which are affected differently by chemical treatment with PbBr2. More generally, our work highlights that in-depth studies using a combination of techniques are necessary to understand nonradiative pathways in fluorescent nanocrystals. Such understanding is essential to optimize synthesis and treatment procedures., ChemE/Opto-electronic Materials

Published
2020
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38. Extending Surface-Enhanced Raman Spectroscopy to Liquids Using Shell-Isolated Plasmonic Superstructures

Author

Inorganic Chemistry and Catalysis, Sub Inorganic Chemistry and Catalysis, Sub Physical and Colloid Chemistry, Physical and Colloid Chemistry, Wondergem, Caterina S, van Swieten, Thomas P, Geitenbeek, Robin G, Erné, Ben H, Weckhuysen, Bert M, Inorganic Chemistry and Catalysis, Sub Inorganic Chemistry and Catalysis, Sub Physical and Colloid Chemistry, Physical and Colloid Chemistry, Wondergem, Caterina S, van Swieten, Thomas P, Geitenbeek, Robin G, Erné, Ben H, and Weckhuysen, Bert M

Published
2019

39. High temperature (nano)thermometers based on LiLuF4:Er3+,Yb3+ nano- and microcrystals. Confounded results for core–shell nanocrystals.

Author

Kaczmarek, Anna M., Suta, Markus, Rijckaert, Hannes, van Swieten, Thomas P., Van Driessche, Isabel, Kaczmarek, Mariusz K., and Meijerink, Andries

Abstract

Recent technological developments require knowledge of temperature down to the micro- or even nano-scale. Lanthanide-doped nanoparticles became a popular tool to achieve this. Their temperature sensitive luminescence enables their application as remote thermometers and for mapping temperature profiles with high spatial resolution. Applicability of luminescence thermometry is, however, often limited at high temperatures. In nanoelectronics or chemical reactors, high temperatures above 500 K are common and new approaches for accurate high temperature sensing need to be developed. In this work, we report three different shapes of upconverting LiLuF4:2% Er3+,18% Yb3+ nanocrystals both with and without shells and study the influence of the shell on the thermometric properties. We observed peculiar behavior of the core–shell particles suggesting the presence of the dopants within the protective and 'undoped' shells. Coating the nanoparticles with a silica layer extends the operational temperature range. In an upconversion (UC) Yb3+–Er3+ system temperature sensing relies on thermal coupling between the 4S3/2 and 2H11/2 energy levels. At sufficiently high temperatures (>550 K), we observe additional thermal coupling involving the higher 4F7/2 energy levels. The larger energy gap allows to increase the relative sensitivity at elevated temperatures and to sustain a high temperature precision over a wider temperature range than for a two-level Boltzmann thermometer. The thermal coupling between the 4S3/2 and 2H11/2 energy levels is used for lower temperature sensing (<550 K) and the 4F7/2 energy level is crucial for higher temperature sensing (>550 K). [ABSTRACT FROM AUTHOR]

Published
2021
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40. Luminescence Thermometry of Pr3+-Doped Sr3Y2Ge3O12and Sr3Sc2Ge3O12Submicron Garnets Spanning the 13–1025 K Range and New Insight to Their Spectroscopy

Author

Bolek, Paulina, van Swieten, Thomas, Zeler, Justyna, Meijerink, Andries, and Zych, Eugeniusz

Abstract

Luminescence thermometry is a highly promising technique for remotely measuring temperature. Nowadays, this method is unrivaled, considering its methodology and high potential for application. However, expanding the operating range of luminescent thermometers is still a challenge. We have successfully demonstrated that by introducing just one dopant, Pr3+, to garnet hosts, we can create a luminescence thermometer that operates in an impressive range of 13–1025 K. Our paper also presents a thorough analysis of the Pr3+location in Sr3Y2Ge3O12and Sr3Sc2Ge3O12garnet hosts, revealing three Pr sites in the former and two in the latter, which has not been previously reported in these phosphors. By using 5d → 4f luminescence below room temperature, we obtained relative thermal sensitivities reaching ∼6%/K. By using the luminescence intensity ratio of the 4f → 4f transitions, we achieved an operating range of 13–1025 K with relative thermal sensitivity ranging from 0.1 to 0.8%/K. Finally, the small and uniform size of the particles, about 150 nm in diameter, is attractive for high spatial resolution applications.

Published
2024
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41. High temperature (nano)thermometers based on LiLuF 4 :Er 3+ ,Yb 3+ nano- and microcrystals. Confounded results for core–shell nanocrystals

Author

Kaczmarek, Anna M., Suta, Markus, Rijckaert, Hannes, van Swieten, Thomas P., Van Driessche, Isabel, Kaczmarek, Mariusz K., Meijerink, Andries, Sub Condensed Matter and Interfaces, and Condensed Matter and Interfaces

Subjects
Materials science, Dopant, Band gap, business.industry, Nanoparticle, 02 engineering and technology, General Chemistry, Atmospheric temperature range, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Photon upconversion, 0104 chemical sciences, Thermometer, Nano, Materials Chemistry, Optoelectronics, 0210 nano-technology, Luminescence, business
Abstract

Recent technological developments require knowledge of temperature down to the micro- or even nano-scale. Lanthanide-doped nanoparticles became a popular tool to achieve this. Their temperature sensitive luminescence enables their application as remote thermometers and for mapping temperature profiles with high spatial resolution. Applicability of luminescence thermometry is, however, often limited at high temperatures. In nanoelectronics or chemical reactors, high temperatures above 500 K are common and new approaches for accurate high temperature sensing need to be developed. In this work, we report three different shapes of upconverting LiLuF4:2% Er3+,18% Yb3+ nanocrystals both with and without shells and study the influence of the shell on the thermometric properties. We observed peculiar behavior of the core–shell particles suggesting the presence of the dopants within the protective and ‘undoped’ shells. Coating the nanoparticles with a silica layer extends the operational temperature range. In an upconversion (UC) Yb3+–Er3+ system temperature sensing relies on thermal coupling between the 4S3/2 and 2H11/2 energy levels. At sufficiently high temperatures (>550 K), we observe additional thermal coupling involving the higher 4F7/2 energy levels. The larger energy gap allows to increase the relative sensitivity at elevated temperatures and to sustain a high temperature precision over a wider temperature range than for a two-level Boltzmann thermometer. The thermal coupling between the 4S3/2 and 2H11/2 energy levels is used for lower temperature sensing ( 550 K).

Full Text
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42. High temperature (nano)thermometers based on LiLuF4:Er3+, Yb3+ nano- and microcrystals. Confounded results for core-shell nanocrystals

Author

Kaczmarek, Anna M., Suta, Markus, Rijckaert, Hannes, van Swieten, Thomas P., Van Driessche, Isabel, Kaczmarek, Mariusz K., and Meijerink, Andries

Subjects
13. Climate action, 7. Clean energy
Abstract

Recent technological developments require knowledge of temperature down to the micro- or even nanoscale. Lanthanide-doped nanoparticles became a popular tool to achieve this. Their temperature sensitive luminescence enables their application as remote thermometer and for mapping temperature profiles with high spatial resolution. Applicability of luminescence thermometry is, however, often limited at high temperatures. In nanoelectronics or chemical reactors, high temperatures above 500 K are common and new approaches for accurate high temperature sensing need to be developed. In this work, we report three different shapes of upconverting LiLuF4: 2% Er3+, 18% Yb3+ nanocrystals both with and without shells and study the influence of the shell on the thermometric properties. We observed peculiar behavior of the core-shell particles suggesting the presence of the dopants within the protective and ‘undoped’ shells. Coating the nanoparticles with a silica layer extends the operational temperature range. In an upconversion (UC) Yb3+-Er3+ system temperature sensing relies on thermal coupling between the 4S3/2 and 2H11/2 energy levels. At sufficiently high temperatures (> 550 K), we observe additional thermal coupling involving the higher 4F7/2 energy levels. The larger energy gap allows to increase the relative sensitivity at elevated temperatures and to sustain a high temperature precision over a wider temperature range than for a two-level Boltzmann thermometer. The thermal coupling between the 4S3/2 and 2H11/2 energy levels is used for lower temperature sensing (< 550 K) and the 4F7/2 energy level is crucial for higher temperature sensing (> 550 K)., This project has received funding from the European Union's Horizon 2020 FET Open programme under grant agreement No 801305 (NanoTBTech).

43. High temperature (nano)thermometers based on LiLuF4:Er3+, Yb3+ nano- and microcrystals. Confounded results for core-shell nanocrystals

Author

Kaczmarek, Anna M., Suta, Markus, Rijckaert, Hannes, van Swieten, Thomas P., Van Driessche, Isabel, Kaczmarek, Mariusz K., and Meijerink, Andries

Subjects
13. Climate action, 7. Clean energy
Abstract

Recent technological developments require knowledge of temperature down to the micro- or even nanoscale. Lanthanide-doped nanoparticles became a popular tool to achieve this. Their temperature sensitive luminescence enables their application as remote thermometer and for mapping temperature profiles with high spatial resolution. Applicability of luminescence thermometry is, however, often limited at high temperatures. In nanoelectronics or chemical reactors, high temperatures above 500 K are common and new approaches for accurate high temperature sensing need to be developed. In this work, we report three different shapes of upconverting LiLuF4: 2% Er3+, 18% Yb3+ nanocrystals both with and without shells and study the influence of the shell on the thermometric properties. We observed peculiar behavior of the core-shell particles suggesting the presence of the dopants within the protective and ‘undoped’ shells. Coating the nanoparticles with a silica layer extends the operational temperature range. In an upconversion (UC) Yb3+-Er3+ system temperature sensing relies on thermal coupling between the 4S3/2 and 2H11/2 energy levels. At sufficiently high temperatures (> 550 K), we observe additional thermal coupling involving the higher 4F7/2 energy levels. The larger energy gap allows to increase the relative sensitivity at elevated temperatures and to sustain a high temperature precision over a wider temperature range than for a two-level Boltzmann thermometer. The thermal coupling between the 4S3/2 and 2H11/2 energy levels is used for lower temperature sensing (< 550 K) and the 4F7/2 energy level is crucial for higher temperature sensing (> 550 K).

44. Mapping Temperature Heterogeneities during Catalytic CO 2 Methanation with Operando Luminescence Thermometry.

Author

Jacobs TS, van Swieten TP, Vonk SJW, Bosman IP, Melcherts AEM, Janssen BC, Janssens JCL, Monai M, Meijerink A, Rabouw FT, van der Stam W, and Weckhuysen BM

Abstract

Controlling and understanding reaction temperature variations in catalytic processes are crucial for assessing the performance of a catalyst material. Local temperature measurements are challenging, however. Luminescence thermometry is a promising remote-sensing tool, but it is cross-sensitive to the optical properties of a sample and other external parameters. In this work, we measure spatial variations in the local temperature on the micrometer length scale during carbon dioxide (CO 2 ) methanation over a TiO 2 -supported Ni catalyst and link them to variations in catalytic performance. We extract local temperatures from the temperature-dependent emission of Y 2 O 3 :Nd 3+ particles, which are mixed with the CO 2 methanation catalyst. Scanning, where a near-infrared laser locally excites the emitting Nd 3+ ions, produces a temperature map with a micrometer pixel size. We first designed the Y 2 O 3 :Nd 3+ particles for optimal temperature precision and characterized cross-sensitivity of the measured signal to parameters other than temperature, such as light absorption by the blackened sample due to coke deposition at elevated temperatures. Introducing reaction gases causes a local temperature increase of the catalyst of on average 6-25 K, increasing with the reactor set temperature in the range of 550-640 K. Pixel-to-pixel variations in the temperature increase show a standard deviation of up to 1.5 K, which are attributed to local variations in the catalytic reaction rate. Mapping and understanding such temperature variations are crucial for the optimization of overall catalyst performance on the nano- and macroscopic scale.

Published
2023
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