Operation of a continuous flow liquid helium magnetic microscopy cryostat as a closed cycle system
Operation of a continuous flow liquid helium magnetic microscopy cryostat as a closed cycle system
We demonstrate successful operation of a continuous flow liquid helium magnetic cryostat (Oxford Instruments, Microstat MO) in closed cycle operation using a modular cryocooling system (ColdEdge Technologies, Stinger). For the system operation, we have developed a custom gas handling manifold and we show that despite the lower cooling power of the cryocooler with respect to the nominal cryostat cooling power requirements, the magnetic cryostat can be operated in a stable manner. We provide the design of the gas handling manifold and a detailed analysis of the system performance in terms of cooling times, magnetic field ramping rates, and vibrations at the sample. Base temperatures can be reached within 10 h while the superconducting magnet can be energized at a ramping rate of 0.5 T/min. Vibrations are measured interferometrically and show amplitudes with a root mean square on the order of 5 nm, permitting the use of the system for sensitive magnetic microscopy experiments.
Barr, K.
da4a0365-28e3-462d-9cce-331244551665
Cookson, Tamsin
70c15876-7c6d-4de5-a0ce-cc4beb12a324
Lagoudakis, K.G.
144a5c8b-d1ef-4259-8d72-5b3b9b927b6b
Barr, K.
da4a0365-28e3-462d-9cce-331244551665
Cookson, Tamsin
70c15876-7c6d-4de5-a0ce-cc4beb12a324
Lagoudakis, K.G.
144a5c8b-d1ef-4259-8d72-5b3b9b927b6b
Barr, K., Cookson, Tamsin and Lagoudakis, K.G.
(2021)
Operation of a continuous flow liquid helium magnetic microscopy cryostat as a closed cycle system.
Review of Scientific Instruments.
Abstract
We demonstrate successful operation of a continuous flow liquid helium magnetic cryostat (Oxford Instruments, Microstat MO) in closed cycle operation using a modular cryocooling system (ColdEdge Technologies, Stinger). For the system operation, we have developed a custom gas handling manifold and we show that despite the lower cooling power of the cryocooler with respect to the nominal cryostat cooling power requirements, the magnetic cryostat can be operated in a stable manner. We provide the design of the gas handling manifold and a detailed analysis of the system performance in terms of cooling times, magnetic field ramping rates, and vibrations at the sample. Base temperatures can be reached within 10 h while the superconducting magnet can be energized at a ramping rate of 0.5 T/min. Vibrations are measured interferometrically and show amplitudes with a root mean square on the order of 5 nm, permitting the use of the system for sensitive magnetic microscopy experiments.
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Accepted/In Press date: 12 November 2021
e-pub ahead of print date: 3 December 2021
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Local EPrints ID: 454232
URI: http://eprints.soton.ac.uk/id/eprint/454232
ISSN: 0034-6748
PURE UUID: 3d986fab-1f64-4a50-a548-49d8368465d6
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Date deposited: 03 Feb 2022 17:44
Last modified: 16 Mar 2024 15:30
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Contributors
Author:
K. Barr
Author:
Tamsin Cookson
Author:
K.G. Lagoudakis
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