Title :
Micro-imaging system using scanning DC-SQUID microscope
Author :
Morooka, T. ; Nakayama, S. ; Odawara, A. ; Ikeda, M. ; Tanaka, S. ; Chinone, K.
Author_Institution :
Seiko Instrum. Inc., Chiba, Japan
fDate :
6/1/1999 12:00:00 AM
Abstract :
A micro-imaging system in a low temperature environment has been developed for the study of superconducting films and magnetic films and for the inspection of superconducting integrated circuits. The system consists of a micro DC-SQUID, a cryostat, a precise scanning stage, and a computer. Two different types of micro DC-SQUIDs were designed. One was a magnetometer (Bz) with a one-turn pick-up coil with a diameter of 10 /spl mu/m, and the other was a gradiometer (dBz/dx) with a planar first-order derivative pick-up coil. Each micro DC-SQUID was integrated on a 3 mm /spl times/3 mm Si chip using thin Nb film fabrication technology. Preliminary experiments were made using the system and several magnetic images were obtained. We present observations of a thin superconducting Nb film pattern by applying the Meissner screening and the magnetic domains of a thin garnet ((YBi)/sub 3/(FeAl)/sub 5/O/sub 12/) film.
Keywords :
SQUID magnetometers; microscopes; (YBi)/sub 3/(FeAl)/sub 5/O/sub 12/; Meissner screening; Nb; Nb thin film fabrication technology; Si chip; cryostat; garnet film; gradiometer; inspection; low temperature instrument; magnetic domain; magnetic film; magnetic imaging; magnetometer; micro-imaging system; pick-up coil; scanning DC-SQUID microscope; superconducting film; superconducting integrated circuit; Garnet films; Inspection; Magnetic domains; Magnetic films; Microscopy; Niobium; Superconducting coils; Superconducting films; Superconducting integrated circuits; Temperature;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
