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14 results on '"Krenek, Stephan"'

1. Photonic and Optomechanical Thermometry

Author

European Commission, Briant, Tristan, Krenek, Stephan, Cupertino, Andrea, Loubar, Ferhat, Braive, Rémy, Weituschat, Lukas, Ramos Vega, Daniel, Martín, María José, Postigo, Pablo Aitor, Casas, Alberto, Eisermann, René, Schmid, Daniel, Tabandeh, Shahin, Hahtela, Ossi, Sara Pourjamal, Kozlova, Olga, Kroker, Stefanie, Dickmann, Walter, Zimmermann, Lars, Winzer, Georg, European Commission, Briant, Tristan, Krenek, Stephan, Cupertino, Andrea, Loubar, Ferhat, Braive, Rémy, Weituschat, Lukas, Ramos Vega, Daniel, Martín, María José, Postigo, Pablo Aitor, Casas, Alberto, Eisermann, René, Schmid, Daniel, Tabandeh, Shahin, Hahtela, Ossi, Sara Pourjamal, Kozlova, Olga, Kroker, Stefanie, Dickmann, Walter, Zimmermann, Lars, and Winzer, Georg

Abstract

Temperature is one of the most relevant physical quantities that affects almost all processes in nature. However, the realization of accurate temperature standards using current temperature references, like the triple point of water, is difficult due to the requirements on material purity and stability of the environment. In addition, in harsh environments, current temperature sensors with electrical readout, like platinum resistors, are difficult to implement, urging the development of optical temperature sensors. In 2018, the European consortium Photoquant, consisting of metrological institutes and academic partners, started investigating new temperature standards for self-calibrated, embedded optomechanical sensor applications, as well as optimised high resolution and high re- liability photonic sensors, to measure temperature at the nano and meso-scales and as a possible replacement for the standard platinum resistant thermometers. This article presents an overview of the results obtained with sensor prototypes that exploit photonic and optomechanical techniques for sensing temperatures over a large temperature range (5 K to 300 K). Different concepts are demon- strated, including ring resonators, ladder-like resonators and suspended membrane optomechanical thermometers, highlighting initial performance and challenges, like self-heating that need to be overcome to realize photonic and optomechanical thermometry applications.

Published
2022

2. Photonic and Optomechanical Thermometry

Author

Briant, Tristan, primary, Krenek, Stephan, additional, Cupertino, Andrea, additional, Loubar, Ferhat, additional, Braive, Rémy, additional, Weituschat, Lukas, additional, Ramos, Daniel, additional, Martin, Maria Jose, additional, Postigo, Pablo A., additional, Casas, Alberto, additional, Eisermann, René, additional, Schmid, Daniel, additional, Tabandeh, Shahin, additional, Hahtela, Ossi, additional, Pourjamal, Sara, additional, Kozlova, Olga, additional, Kroker, Stefanie, additional, Dickmann, Walter, additional, Zimmermann, Lars, additional, Winzer, Georg, additional, Martel, Théo, additional, Steeneken, Peter G., additional, Norte, Richard A., additional, and Briaudeau, Stéphan, additional

Published
2022
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4. Metrological Characterization of a High-Temperature Hybrid Sensor Using Thermal Radiation and Calibrated Sapphire Fiber Bragg Grating for Process Monitoring in Harsh Environments

Author

Eisermann, René, primary, Krenek, Stephan, additional, Habisreuther, Tobias, additional, Ederer, Petra, additional, Simonsen, Sigurd, additional, Mathisen, Helge, additional, Elsmann, Tino, additional, Edler, Frank, additional, Schmid, Daniel, additional, Lorenz, Adrian, additional, and Olsen, Åge, additional

Published
2022
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9. Extension and improvement of the methanol‐d4 NMR thermometer calibration.

Author

Karschin, Niels, Krenek, Stephan, Heyer, Dieter, and Griesinger, Christian

Subjects
*MAGNETIC field effects, *THERMOMETERS, *NMR spectrometers, *CALIBRATION, *TEMPERATURE sensors
Abstract

NMR thermometers are a convenient way to determine the temperature inside the sample of an NMR spectrometer. They rely on signals with strongly temperature‐dependent chemical shifts, often of OH groups; 99.8% perdeuterated methanol is an established example which is particularly well suited for modern, high‐sensitivity spectrometers, but it is so far calibrated only in the range of 282 to 330 K. In this work, we extend this calibration to the entire liquid range of methanol, 175 to 338 K. Additionally, we use a temperature sensor calibrated traceably to the International Temperature Scale (ITS‐90) and accounted for the magnetic field effect on the sensor, yielding a more accurate calibration curve with an uncertainty (2σ) varying between 25 and 190 mK. [ABSTRACT FROM AUTHOR]

Published
2022
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10. Dynamische Emissionsgradmessung im Hochtemperaturbereich

Author

Krenek, Stephan

Subjects
Graphit, hohe Temperaturen, Messmethode, Emissionsgrad, LFA, Strahlungsthermometrie, Kalorimetrie, Pulsheizung, Laser-Flash-Verfahren, Wolfram
Abstract

PTB-Bericht Th-8, ISBN 978-3-95606-287-2, ISSN 1614-9327, Das Hauptziel dieser Arbeit ist die Entwicklung und Realisierung einer neuen Messmethode zur Untersuchung des gerichteten spektralen Emissionsgrades bei Temperaturen über 1000 °C. Die sogenannte dynamische Emissionsgradmessung basiert auf dem Laser-Flash-Verfahren. Eine Probe wird dabei durch einen Laserpuls erwärmt und ihre relative Temperaturänderung gemessen. Dieses Verfahren wird zur Emissionsgradmessung um die Absolutmessung der Laserenergie und der Temperaturänderung erweitert. Zur Realisierung der neuen Messmethode werden drei Themenfelder bearbeitet: Erstens wird ein Verfahren zur in situ Messung der Laserenergie entwickelt und die Energieverteilung der Laserstrahlung am Probenort charakterisiert. Zweitens wird ein dediziertes Strahlungsthermometer charakterisiert und kalibriert, um die Temperaturänderung im adiabatischen Grenzfall messen zu können. Außerdem wird die Theorie des Laser-Flash-Verfahrens für die Emissionsgradmessung erweitert. Drittens wird ein Modell der Strahlungsbilanz für die radiometrische Temperaturmessung erstellt und so der Einfluss der Hintergrundstrahlung des Ofens minimiert. Es wird ein Messplatz zur Validierung dieser Messmethode aufgebaut und mit diesem Graphit und Wolfram untersucht. Der normale spektrale Emissionsgrad von Graphit wird bei 1064 nm und von ca. 750 °C bis 1500 °C gemessen. Dabei werden Unsicherheiten von unter 0,02 (k = 1) erreicht und durch andere Quellen bestätigt. Mit der Messung von speziell präparierten Wolfram-Proben kann die Konsistenz von drei unterschiedlichen physikalischen Prinzipien zur dynamischen Emissionsgradmessung (radiometrisch, kalorimetrische und kombiniert) nachgewiesen werden. Die Unsicherheiten der Messungen werden analysiert und die zukünftige Optimierung des Messplatzes diskutiert.

Published
2016
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12. Temperatur-Komparator auf Basis eines druckgeregelten Wärmerohres.

Author

Krenek, Stephan and Rudtsch, Steffen

Subjects
HEAT pipes, HEAT-transfer media, TEMPERATURE measurements, ISOTHERMAL processes, PIPE testing
Abstract

Copyright of Technisches Messen is the property of De Gruyter and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2018
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14. Extension and improvement of the methanol-d 4 NMR thermometer calibration.

Author

Karschin N, Krenek S, Heyer D, and Griesinger C

Subjects
Calibration, Magnetic Resonance Imaging, Magnetic Resonance Spectroscopy, Methanol, Thermometers
Abstract

NMR thermometers are a convenient way to determine the temperature inside the sample of an NMR spectrometer. They rely on signals with strongly temperature-dependent chemical shifts, often of OH groups; 99.8% perdeuterated methanol is an established example which is particularly well suited for modern, high-sensitivity spectrometers, but it is so far calibrated only in the range of 282 to 330 K. In this work, we extend this calibration to the entire liquid range of methanol, 175 to 338 K. Additionally, we use a temperature sensor calibrated traceably to the International Temperature Scale (ITS-90) and accounted for the magnetic field effect on the sensor, yielding a more accurate calibration curve with an uncertainty (2σ) varying between 25 and 190 mK., (© 2021 The Authors. Magnetic Resonance in Chemistry published by John Wiley & Sons Ltd.)

Published
2022
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