Title :
Magnetic vortices in Sub-100 nm magnets
Author :
Roshchin, Igor V. ; Li, Chang-Peng ; Suhl, Harry ; Batlle, Xavier ; Roy, S. ; Sinha, Sunil K. ; Park, S. ; Pynn, Roger ; Fitzsimmons, M.R. ; Mejía-López, Jose ; Altbir, Dora ; Romero, A.H. ; Dumas, R. ; Liu, Kai ; Schuller, Ivan K.
Author_Institution :
Phys. Dept., Texas A&M Univ., College Station, TX, USA
Abstract :
Presented is a quantitative study of the magnetic vortex state and the vortex core in sub-100 nm magnetic dots. Arrays of magnetic nanodots covering over 1 cm2 are fabricated using self-assembled nanopores in anodized alumina. Transition from a vortex to a single domain state for the Fe dots is studied by magnetization measurements (SQUID, VSM, and MOKE) as a function of the dots size and magnetic field. Micromagnetic and Monte Carlo simulations confirm the experimental observations. Thermal activation and exchange bias have a large effect on the vortex nucleation field. Quantitative analysis of grazing incidence small angle neutron scattering measurements with polarization analysis, performed on 65 nm Fe dots yields the magnetization of the vortex core of 140plusmn50 emu/cm3 and its diameter of 19plusmn4 nm, in agreement with the simulations results.
Keywords :
Kerr magneto-optical effect; Monte Carlo methods; SQUIDs; exchange interactions (electron); iron; magnetic domains; magnetic structure; magnetic transitions; magnetometers; micromagnetics; nanofabrication; nanostructured materials; neutron diffraction; nucleation; self-assembly; Fe; MOKE; Monte Carlo simulation; SQUID; VSM; anodized alumina; exchange bias; grazing incidence small angle neutron scattering; magnetic dot arrays; magnetic field; magnetic vortex state; magnetization; micromagnetic simulation; polarization analysis; quantitative analysis; self-assembled nanopores; spin configuration; thermal activation; vortex core; vortex nucleation field; vortex-single domain state transition; Iron; Magnetic analysis; Magnetic cores; Magnetic domains; Magnetic field measurement; Magnetization; Magnets; Nanoporous materials; Performance analysis; Self-assembly;
Conference_Titel :
Electromagnetics in Advanced Applications, 2009. ICEAA '09. International Conference on
Conference_Location :
Torino
Print_ISBN :
978-1-4244-3385-8
Electronic_ISBN :
978-1-4244-3386-5
DOI :
10.1109/ICEAA.2009.5297777
