Measurement of the Ultrasound Induced Temperature Change in an Ultrasonic Assisted Silver Sintering Process

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Details

Original languageEnglish
Title of host publicationIEEE Sensors 2023 Conference Proceedings
ISBN (electronic)979-8-3503-0387-2
Publication statusPublished - 2023

Publication series

NameProceedings of IEEE Sensors
ISSN (Print)1930-0395
ISSN (electronic)2168-9229

Abstract

The process of silver sintering is a key technology in the fabrication of advanced electronic devices. In this study, a multilayer thin film sensor is built and integrated into the joining process of ultrasonic assisted silver sintering to measure the influence of ultrasound on the sintering temperature. The sensor is designed as a resistance thermometer with platinum as the sensing layer. The results show almost a linear relationship between the applied ultrasonic power and the measured temperature increase with a maximum of 4.5 °C at a power level of 7000 mW. In addition, higher normal forces result in greater temperature increase.

Keywords

    platinum, silver sintering, temperature thin film sensor, ultrasound

ASJC Scopus subject areas

Cite this

Measurement of the Ultrasound Induced Temperature Change in an Ultrasonic Assisted Silver Sintering Process. / Hadeler, Steffen; Long, Yangyang; Twiefel, Jens et al.
IEEE Sensors 2023 Conference Proceedings. 2023. (Proceedings of IEEE Sensors).

Research output: Chapter in book/report/conference proceedingConference contributionResearchpeer review

Hadeler, S, Long, Y, Twiefel, J & Wurz, MC 2023, Measurement of the Ultrasound Induced Temperature Change in an Ultrasonic Assisted Silver Sintering Process. in IEEE Sensors 2023 Conference Proceedings. Proceedings of IEEE Sensors. https://doi.org/10.1109/SENSORS56945.2023.10325249
Hadeler, S., Long, Y., Twiefel, J., & Wurz, M. C. (2023). Measurement of the Ultrasound Induced Temperature Change in an Ultrasonic Assisted Silver Sintering Process. In IEEE Sensors 2023 Conference Proceedings (Proceedings of IEEE Sensors). https://doi.org/10.1109/SENSORS56945.2023.10325249
Hadeler S, Long Y, Twiefel J, Wurz MC. Measurement of the Ultrasound Induced Temperature Change in an Ultrasonic Assisted Silver Sintering Process. In IEEE Sensors 2023 Conference Proceedings. 2023. (Proceedings of IEEE Sensors). doi: 10.1109/SENSORS56945.2023.10325249
Hadeler, Steffen ; Long, Yangyang ; Twiefel, Jens et al. / Measurement of the Ultrasound Induced Temperature Change in an Ultrasonic Assisted Silver Sintering Process. IEEE Sensors 2023 Conference Proceedings. 2023. (Proceedings of IEEE Sensors).
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abstract = "The process of silver sintering is a key technology in the fabrication of advanced electronic devices. In this study, a multilayer thin film sensor is built and integrated into the joining process of ultrasonic assisted silver sintering to measure the influence of ultrasound on the sintering temperature. The sensor is designed as a resistance thermometer with platinum as the sensing layer. The results show almost a linear relationship between the applied ultrasonic power and the measured temperature increase with a maximum of 4.5 °C at a power level of 7000 mW. In addition, higher normal forces result in greater temperature increase.",
keywords = "platinum, silver sintering, temperature thin film sensor, ultrasound",
author = "Steffen Hadeler and Yangyang Long and Jens Twiefel and Wurz, {Marc Christopher}",
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AB - The process of silver sintering is a key technology in the fabrication of advanced electronic devices. In this study, a multilayer thin film sensor is built and integrated into the joining process of ultrasonic assisted silver sintering to measure the influence of ultrasound on the sintering temperature. The sensor is designed as a resistance thermometer with platinum as the sensing layer. The results show almost a linear relationship between the applied ultrasonic power and the measured temperature increase with a maximum of 4.5 °C at a power level of 7000 mW. In addition, higher normal forces result in greater temperature increase.

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