Piezospectroscopic measurement of high-frequency vibrations in a pulse-tube cryostat

Vibrations in cryocoolers are a recurrent concern to the end user. They appear in different parts of the acoustic spectrum depending on the refrigerator type, Gifford McMahon or pulse-tube, and with a variable coupling strength to the physical system under interest. Here, we use the piezospectroscop...

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Published in:Review of scientific instruments 2019-03, Vol.90 (3), p.034901-034901
Main Authors: Louchet-Chauvet, Anne, Ahlefeldt, Rose, Chanelière, Thierry
Format: Article
Language:English
Subjects:
Atomic Physics
Doped crystals
Instrumentation and Detectors
Physics
Pulse tubes
Rare earth elements
Scientific apparatus & instruments
Vibration analysis
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description Vibrations in cryocoolers are a recurrent concern to the end user. They appear in different parts of the acoustic spectrum depending on the refrigerator type, Gifford McMahon or pulse-tube, and with a variable coupling strength to the physical system under interest. Here, we use the piezospectroscopic effect in rare-earth doped crystals at a low temperature as a high resolution, contact-less probe for the vibrations. With this optical spectroscopic technique, we obtain and analyze the vibration spectrum up to 700 kHz of a 2 kW pulse-tube cooler. We attempt an absolute calibration based on known experimental parameters to make our method partially quantitative and to provide a possible comparison with other well-established techniques.
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source American Institute of Physics:Jisc Collections:Transitional Journals Agreement 2021-23 (Reading list); AIP - American Institute of Physics
subjects Atomic Physics
Doped crystals
Instrumentation and Detectors
Physics
Pulse tubes
Rare earth elements
Scientific apparatus & instruments
Vibration analysis
title Piezospectroscopic measurement of high-frequency vibrations in a pulse-tube cryostat
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