Sub-fT/Hz1/2 resolution and field-stable SQUID magnetometer based on low parasitic capacitance sub-micrometer cross-type Josephson tunnel junctions

► A new technology for the fabrication of small low capacitance junctions is presented. ► Within this technology highly sensitive SQUID magnetometers have been fabricated. ► They show noise levels down to 0.3fT/Hz1/2 and voltage swings of more than 150μVpp. ► They withstand magnetic background field...

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Bibliographic Details
Published in:Physica. C, Superconductivity Vol. 482; pp. 27 - 32
Main Authors: Schmelz, M., Stolz, R., Zakosarenko, V., Schönau, T., Anders, S., Fritzsch, L., Mück, M., Meyer, M., Meyer, H.-G.
Format: Journal Article Conference Proceeding
Language:English
Published: Amsterdam Elsevier B.V 20-11-2012
Elsevier
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Summary:► A new technology for the fabrication of small low capacitance junctions is presented. ► Within this technology highly sensitive SQUID magnetometers have been fabricated. ► They show noise levels down to 0.3fT/Hz1/2 and voltage swings of more than 150μVpp. ► They withstand magnetic background fields during cool-down of up to 6.5mT. ► They completely recover from magnetization pulses of up to 76mT. We review the development of low parasitic capacitance sub-micrometer cross-type Josephson tunnel junctions for their use in highly sensitive and field-stable SQUID magnetometers. The potential of such junctions is shown on I–V characteristics as well as on Fraunhofer diffraction patterns. The evaluation of Fiske steps lead to a specific junction capacitance of about 62fF/μm2 for a critical current density of about 1.7kA/cm2. The avoidance of any idle-region – the undesired overlap between superconducting electrodes around the junction – due to a self-aligned junction definition process lead to highly sensitive SQUIDs; multiloop SQUID magnetometers exhibiting exceptionally low magnetic field noise levels as low as 0.3fT/Hz1/2, as well as large usable voltage swings of more than 150μVpp. Furthermore, junction dimensions in the sub-micrometer range allowed for very high tolerable background fields during cool-down of up to 6.5mT. In operation mode, the SQUID magnetometers recovered completely from magnetization pulses of up to 76mT. With respect to their easy and reliable usage as well as their high sensitivity, the presented SQUID sensors are adequate for many applications, like in geophysics, biomagnetism or low-field magnetic resonance imaging.
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ISSN:0921-4534
1873-2143
DOI:10.1016/j.physc.2012.06.005