Quantifying dipolar mean-field interactions from hysteresis and initial curves: A fast Magnetometry route to iSFD Deshearing

We present a fast magnetometry route to quantify dipolar mean-field coupling ¿ and recover the intrinsic switching-field distribution (iSFD) using only a major hysteresis loop plus the initial magnetization curve acquired from an AC-demagnetized state. Within a Stoner¿Wohlfarth/Preisach mean-field picture, interaction-induced shearing broadens susceptibilities; ¿ is obtained from area identities at high remanence and, for low-remanence systems, from an offset-free derivative estimator. Validation on Sr-hexaferrite nanoparticles embedded in PVA nanofibers yields ¿¿¿535,¿740 and ¿ 840 Oe for 1.5%, 2.0% and 2.5% loadings, respectively, and deshearing collapses loops and susceptibilities onto their intrinsic references. The workflow includes two internal consistency checks, post-deshearing antisymmetry of branches and initial-curve/upper-branch overlap for H¿0, making the estimate auditable. Compared to ¿M/Henkel and FORC, the method requires a single loop plus one initial curve and remains robust in the presence of reversible contributions. © 2026 The Authors.

Quantifying dipolar mean-field interactions from hysteresis and initial curves: A fast Magnetometry route to iSFD Deshearing Academic Article in Scopus