Improvement of Performance of SQUID Magnetometer System for Highly Sensitive Geomagnetic Field Measurements

Abstract

We have been developing a LTS superconducting quantum interference device (SQUID) magnetometer system aiming at highly sensitive geomagnetic field measurements with an intended magnetic field noise floor of approximately 10 fT/√Hz in the frequency range below 100 Hz. However, our previous system using SQUID magnetometers with the noise of ∼30 fT/√Hz had the system noise of ∼200 fT/√Hz, and the measurable frequency bandwidth was limited up to ∼30 Hz. This unsatisfactory performance was due to the thermal noise and cutoff frequency of an electromagnetic (EM) shield made of copper foil, which covered the SQUID magnetometers cylindrically, because its design was not optimum. To improve the instrument performance, we fabricated SQUID magnetometers having a noise floor of ∼10 fT/√Hz. We also evaluated the thermal noise and cutoff frequency of pure copper foils with different values of thickness and purity. Adopting a 0.08-mm-thick copper foil as an EM shield for the new SQUID magnetometers, the system noise and frequency bandwidth were improved to ∼25 fT/√Hz and ∼1 kHz, respectively. Using this improved system, we measured geomagnetic fields and confirmed that the background signal in the Z component was smaller compared with the measurement result obtained using the previous system.