Low‐frequency noise reduction in SQUID measurements using a laser‐driven superconducting switch. Part A: Direct input circuit switching

Low‐frequency noise reduction in SQUID measurements using a laser‐driven superconducting switch. Part A: Direct input circuit switching

We describe a technique for substantially decreasing the noise in SQUID measurement applications which are intrinsically low frequency or dc and thus fall below the 1/f knee in the SQUID noise energy spectrum. The technique involves reversing the SQUID input leads at a chopping frequency of ∼100 Hz...

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Veröffentlicht in:Rev. Sci. Instrum.; (United States) 1989-02, Vol.60 (2), p.202-208
Hauptverfasser: Anderson, J. T., Cabrera, B., Taber, M. A., Felch, S. B., Tate, J.
Format: Artikel
Sprache:eng
Schlagworte:
420201 - Engineering- Cryogenic Equipment & Devices
CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
ELECTRICAL EQUIPMENT
ELECTRONIC EQUIPMENT
FLUXMETERS
FREQUENCY DEPENDENCE
INHIBITION
LASERS
MEASURING INSTRUMENTS
MICROWAVE EQUIPMENT
SIGNAL-TO-NOISE RATIO
SQUID DEVICES
SUPERCONDUCTING DEVICES
SWITCHES
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Zusammenfassung:We describe a technique for substantially decreasing the noise in SQUID measurement applications which are intrinsically low frequency or dc and thus fall below the 1/f knee in the SQUID noise energy spectrum. The technique involves reversing the SQUID input leads at a chopping frequency of ∼100 Hz using laser‐driven switches which form a double‐pole–double‐throw network. For sufficiently low noise switching, the demodulate output no longer contains the SQUID low‐frequency noise but rather noise at the SQUID white‐noise floor. We present data demonstrating the low noise performance of a single laser switch, and include the electronics design required for the full implementation of the scheme.
ISSN:0034-6748
1089-7623
DOI:10.1063/1.1140461