Surface spin canting in Fe3O4 and CoFe2O4 nanoparticles probed by high resolution electron energy loss spectroscopy

TL;DR

This study uses high resolution electron energy loss spectroscopy to analyze surface spin canting in Fe3O4 and CoFe2O4 nanoparticles, revealing detailed magnetic surface structures and angles with high spatial resolution.

Contribution

Developed a novel HR-EELS technique capable of atomic plane resolution to study surface spin canting in magnetic nanoparticles, providing atom site-specific information and insights into magnetic interactions.

Findings

Confirmed uniform spin canting in CFO with atom site-specific details.

Deduced core-shell structure and canting angles in Fe3O4 nanoparticles.

Highlighted HR-EELS as a powerful alternative to neutron scattering for magnetic surface analysis.

Abstract

High resolution electron energy loss spectroscopy (HR-EELS) is utilized to probe the surface spin canting in nanoparticles of two technologically important magnetic materials, i.e. Fe3O4 and CoFe2O4 (CFO). A soft experimental technique is developed that is capable of extracting EELS spectra with one atomic plane resolution recorded in a single frame. This yields information at different depth of the nanoparticle from the surface to the core regions with high signal to noise ratio and without beam damage. This enables comparing the fine structures between the surface and core regions of the nanoparticles. The results confirm earlier observations of uniformly oriented spin canting structure for CFO with additional information on atom site-selective spin canting information. In case of Fe3O4 preferred canting orientation forming core and shell structure is deduced. Unlike earlier reports based on polarized spin-flip neutron scattering measurement, it is possible to narrow down the possible canting angles for Fe3O4 (Td, Oh tilts 40{\deg}, 40{\deg}) and CFO (Td, Oh tilts 17{\deg}, 17{\deg}) from the experimental spectra combined with the first principle based calculation considering non-collinear magnetism. In addition, the role of Dzyaloshinskii-Moriya interaction in stabilizing the spin canting at the nanoparticle surface is discussed. The results demonstrate that HREELS can be a powerful technique to probe the magnetic structure in nano-dimensional systems and has advantages over neutron based techniques in terms of superior spatial resolution, site specific information and easy of sample preparation.