1. In-situ magnetization/heating electron holography to study the magnetic ordering in arrays of nickel metallic nanowires
- Author
-
Jason Giuliani, Carlos Monton, Arturo Ponce, Eduardo Ortega, and Ulises Santiago
- Subjects
010302 applied physics ,Magnetic Characterization ,Materials science ,Condensed matter physics ,Nanowire ,General Physics and Astronomy ,Physics::Optics ,02 engineering and technology ,021001 nanoscience & nanotechnology ,Magnetocrystalline anisotropy ,01 natural sciences ,7. Clean energy ,Electron holography ,lcsh:QC1-999 ,Magnetization ,Magnetic anisotropy ,Condensed Matter::Materials Science ,Electron diffraction ,Ferromagnetism ,0103 physical sciences ,Precession electron diffraction ,THE 62ND MMM CONFERENCE PAPERS ,0210 nano-technology ,lcsh:Physics - Abstract
Magnetic nanostructures of different size, shape, and composition possess a great potential to improve current technologies like data storage and electromagnetic sensing. In thin ferromagnetic nanowires, their magnetization behavior is dominated by the competition between magnetocrystalline anisotropy (related to the crystalline structure) and shape anisotropy. In this way electron diffraction methods like precession electron diffraction (PED) can be used to link the magnetic behavior observed by Electron Holography (EH) with its crystallinity. Using off-axis electron holography under Lorentz conditions, we can experimentally determine the magnetization distribution over neighboring nanostructures and their diamagnetic matrix. In the case of a single row of nickel nanowires within the alumina template, the thin TEM samples showed a dominant antiferromagnetic arrangement demonstrating long-range magnetostatic interactions playing a major role.
- Published
- 2018