Field Dependence of Magnetic Disorder in Nanoparticles

The performance characteristics of magnetic nanoparticles toward application, e.g., in medicine and imaging or as sensors, are directly determined by their magnetization relaxation and total magnetic moment. In the commonly assumed picture, nanoparticles have a constant overall magnetic moment origi...

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Published inPhysical review. X Vol. 10; no. 3; p. 031019
Main Authors Zákutná, Dominika, Nižňanský, Daniel, Barnsley, Lester C., Babcock, Earl, Salhi, Zahir, Feoktystov, Artem, Honecker, Dirk, Disch, Sabrina
Format Journal Article
LanguageEnglish
Published College Park American Physical Society 01.07.2020
Subjects
Beads
Coherence
Data storage
Environmental cleanup
Ferrites
Magnetic fields
Magnetic induction
Magnetic moments
Magnetic properties
Magnetism
Magnetization
Medicine
Nanomaterials
Nanoparticles
Neutron scattering
Polarization
Spin structure
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Summary:The performance characteristics of magnetic nanoparticles toward application, e.g., in medicine and imaging or as sensors, are directly determined by their magnetization relaxation and total magnetic moment. In the commonly assumed picture, nanoparticles have a constant overall magnetic moment originating from the magnetization of the single-domain particle core surrounded by a surface region hosting spin disorder. In contrast, this work demonstrates the significant increase of the magnetic moment of ferrite nanoparticles with an applied magnetic field. At low magnetic field, the homogeneously magnetized particle core initially coincides in size with the structurally coherent grain of 12.8(2) nm diameter, indicating a strong coupling between magnetic and structural disorder. Applied magnetic fields gradually polarize the uncorrelated, disordered surface spins, resulting in a magnetic volume more than 20% larger than the structurally coherent core. The intraparticle magnetic disorder energy increases sharply toward the defect-rich surface as established by the field dependence of the magnetization distribution. In consequence, these findings illustrate how the nanoparticle magnetization overcomes structural surface disorder. This new concept of intraparticle magnetization is deployable to other magnetic nanoparticle systems, where the in-depth knowledge of spin disorder and associated magnetic anisotropies are decisive for a rational nanomaterials design.
ISSN:2160-3308
2160-3308
DOI:10.1103/PhysRevX.10.031019