Title :
Magnetic interactions in Fe films sputtered on nanochannel alumina
Author :
Butera, A. ; Weston, J.L. ; Barnard, J.A.
Author_Institution :
Dept. of Metall. & Mater. Eng., Alabama Univ., Tuscaloosa, AL, USA
fDate :
9/1/1997 12:00:00 AM
Abstract :
We present in this work a study of the magnetic interactions observed in Fe films sputtered onto the surface of commercial porous nanochannel alumina. These films, which grow in a “network-like” structure, have been characterized by delta M plots, magnetic viscosity and activation volume as a function of film thickness (5 nm⩽φ⩽100 nm) and substrate pore size (20 nm, 100 nm and 200 nm average diameter). We have found a maximum in the remanent coercivity and a minimum in the interparticle interaction for a film thickness φ~20 nm for the three substrates. The behavior of the magnetic viscosity and the activation volume on the other hand is dependent on the pore size. We have interpreted our results in terms of the different porosity of the substrates, As the porosity is smaller for the substrates with smaller holes, the continuous film behavior is approached first because the pores fill in more rapidly
Keywords :
alumina; coercive force; ferromagnetic materials; iron; magnetic particles; magnetic thin films; magnetisation reversal; nanostructured materials; porous materials; remanence; sputtered coatings; substrates; superparamagnetism; 100 nm; 20 nm; 200 nm; 5 to 100 nm; Al2O3; Fe; Fe sputtered films; activation volume; commercial porous nanochannel alumina; continuous film behavior; delta M plots; film thickness; interparticle interaction; magnetic interactions; magnetic storage media; magnetic viscosity; nanochannel alumina; network-like structure; porosity; remanent coercivity; substrate pore size; substrates; Coercive force; Iron; Magnetic films; Magnetic separation; Magnetic susceptibility; Magnetization reversal; Saturation magnetization; Substrates; Temperature measurement; Viscosity;
Journal_Title :
Magnetics, IEEE Transactions on
