📝 SummarXiv

Abstract

This work explores the behaviour of demagnetizing tensors for general ellipsoids under arbitrary rotations in homogeneous magnetic fields. The work is motivated by the concerns in magnetic resonance imaging safety and their practical evaluation in clinical environments. Whereas demagnetizing tensor is a well-defined concept in the principal axes, its transformation under three-dimensional reorientation is often overlooked - a justifiable omission for solutions derived from Poisson equation, where the tensor can be directly rotated. However, this does not hold for common approximations, where such tensor is not explicitly defined. This work demonstrates the validity of directly rotating the orthogonal basis solutions, derived from Poissons equation, and uses the procedure to evaluate a practical approximation, based on orthogonal area-projections. The tensor rotation approach is also applied to generalize force and torque calculations for ellipsoids under three-dimensional re-orientation. The results show an exact match for translation force and torque when compared to the standard single axis rotation. Additionally, a unique connection to the well-known MRI magic angle is found as the point of convergence for prolate spheroid aspect ratios while solving the corresponding saturation field magnitudes. Finally, the evaluated approximate method was demonstrated to perform fairly across prolate and oblate spheroids. Similar approximations might extend to irregular shapes, but numerical validation would likely remain preferable due to the complexity of internal field distributions.