Superconducting Radiofrequency Probes for Magnetic Resonance Microscopy, Simulation and Experiments

In magnetic resonance microscopy, insufficient signal-to-noise ratio currently limits imaging performance. Superconducting probes can potentially increase the sensitivity of the magnetic resonance experiment. However, many superconducting probes failed to entirely deliver the expected increase in signal-to-noise ratio.

We present a method based on finite-element radiofrequency simulations. The radiofrequency model computes several figures of merit of a probe, namely: i) the resonant frequency, ii) the impedance, iii) the magnetic field homogeneity, iv) the filling factor, and v) the sensitivity. The probe is constituted by several components. The method calculates the electromagnetic losses induced by every component within the probe, and identifies the component limiting the sensitivity of the probe. Subsequently, the probe design can be improved iteratively.

We show that the sensitivity of an existing superconducting Helmholtz pair can be improved by increasing the filling factor of the probe and cooling the radiofrequency shield, which was implemented in the design of a new superconducting probe. The second probe exhibits a sensitivity three times as high, leading to improved imaging performance.