English

Scanning SQUID susceptometers with sub-micron spatial resolution

Superconductivity 2016-09-21 v2

Abstract

Superconducting QUantum Interference Device (SQUID) microscopy has excellent magnetic field sensitivity, but suffers from modest spatial resolution when compared with other scanning probes. This spatial resolution is determined by both the size of the field sensitive area and the spacing between this area and the sample surface. In this paper we describe scanning SQUID susceptometers that achieve sub-micron spatial resolution while retaining a white noise floor flux sensitivity of 2μΦ0/Hz1/2\approx 2\mu\Phi_0/Hz^{1/2}. This high spatial resolution is accomplished by deep sub-micron feature sizes, well shielded pickup loops fabricated using a planarized process, and a deep etch step that minimizes the spacing between the sample surface and the SQUID pickup loop. We describe the design, modeling, fabrication, and testing of these sensors. Although sub-micron spatial resolution has been achieved previously in scanning SQUID sensors, our sensors not only achieve high spatial resolution, but also have integrated modulation coils for flux feedback, integrated field coils for susceptibility measurements, and batch processing. They are therefore a generally applicable tool for imaging sample magnetization, currents, and susceptibilities with higher spatial resolution than previous susceptometers.

Keywords

Cite

@article{arxiv.1605.09483,
  title  = {Scanning SQUID susceptometers with sub-micron spatial resolution},
  author = {John R. Kirtley and Lisa Paulius and Aaron J. Rosenberg and Johanna C. Palmstrom and Connor M. Holland and Eric M. Spanton and Daniel Schiessl and Colin L. Jermain and Jonathan Gibbons and Y. -K. -K. Fung and Martin E. Huber and Daniel C. Ralph and Mark B. Ketchen and Gerald W. Gibson and Kathryn A. Moler},
  journal= {arXiv preprint arXiv:1605.09483},
  year   = {2016}
}

Comments

13 figures

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