Magnetic Domain Suppression in Fe/Si Multilayers with 11B4C Integration for Polarizing Neutron Optics

This study explores the impact of boron carbide (B4C) addition on magnetic domains within Fe/Si multilayers through off-specular neutron scattering with polarization analysis. The incorporation of B4C induces amorphization in layers, disrupting magnetic domain structures. Analysis of the scattering patterns reveals that magnetic domains in pure Fe/Si multilayers exhibit no significant correlation between layers, resulting in a specific diffuse off-specular scattering signal, while the B4C incorporated Fe/Si multilayers revealed no diffuse off-specular scattering. We offer a qualitative interpretation of these scattering phenomena and accurately model the observed diffuse patterns using the distorted wave Born approximation. Low-energy {\mu}+SR measurements further reveal that local magnetic fields in Fe/Si and Fe/Si + B4C multilayers are more easily manipulated by external fields in B4C-containing layers, with enhanced field uniformity in the muon length-scale. Our findings provide insights into the role of B4C in altering magnetic domain arrangements within Fe/Si multilayers, contributing to advances in the design of magnetic materials and neutron polarization coatings.