Add to ORKGThe equation of motion for ferromagnetic domain walls is compared with initial permeability measurements of Co-based soft ferromagnetic amorphous ribbons at frequencies in the range 100 Hz-13 MHz. The analysis of these results by complex permeability methods leads to an equivalent circuit formed by a parallel RL arrangement in series with a small resistance R(W) due to resistance of the measurement coil. This equivalent circuit, however, cannot model the irreversible magnetization behavior for fields higher than the pinning (or propagation) field. It is shown that the equation of motion is also consistent only with the reversible magnetization mechanism, if the displacement term, x, represents instead the bulging of the pinned wall. The cor...
[EN] Magnetostrictive Fe-base amorphous wires spontaneously exhibit square-shaped hysteresis loops t...
Bitter method is most commonly observing way of the magnetic domain walls even though it is limited ...
Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Materials Science and Engineering, 20...
The equation of motion for ferromagnetic domain walls is compared with initial permeability measurem...
The nature of the resistance term in the equivalent circuit which represents the behaviour of revers...
Magnetization mechanisms in Metglas(R) 2605 ferromagnetic amorphous ribbons have been investigated b...
Recent results concerning domain structure and domain-wall motion in amorphous soft ferromagnets are...
The initial magnetic permeability, mu0, of Vitrovac 6025(R) amorphous ribbons has been investigated ...
The domain wall movement and magnetization rotations processes are separated experimentally in quasi...
An experiment, measuring the changes of impedance in a magnetic wire, caused by the presence of a si...
In this work, the magnetization dynamics of soft magnetic materials is studied with the aid of trans...
We study the domain wall motion in a disordered weak ferromagnet, induced by injecting a spin curren...
International audienceUltrasoft magnetic materials, such as amorphous, nanocrystalline, and polycrys...
International audienceMultilayer cores are suitable for integrated planar magnetic components. We pr...
A feedback technique has been developed to perform permeability relaxation measurements at constant ...
[EN] Magnetostrictive Fe-base amorphous wires spontaneously exhibit square-shaped hysteresis loops t...
Bitter method is most commonly observing way of the magnetic domain walls even though it is limited ...
Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Materials Science and Engineering, 20...
The equation of motion for ferromagnetic domain walls is compared with initial permeability measurem...
The nature of the resistance term in the equivalent circuit which represents the behaviour of revers...
Magnetization mechanisms in Metglas(R) 2605 ferromagnetic amorphous ribbons have been investigated b...
Recent results concerning domain structure and domain-wall motion in amorphous soft ferromagnets are...
The initial magnetic permeability, mu0, of Vitrovac 6025(R) amorphous ribbons has been investigated ...
The domain wall movement and magnetization rotations processes are separated experimentally in quasi...
An experiment, measuring the changes of impedance in a magnetic wire, caused by the presence of a si...
In this work, the magnetization dynamics of soft magnetic materials is studied with the aid of trans...
We study the domain wall motion in a disordered weak ferromagnet, induced by injecting a spin curren...
International audienceUltrasoft magnetic materials, such as amorphous, nanocrystalline, and polycrys...
International audienceMultilayer cores are suitable for integrated planar magnetic components. We pr...
A feedback technique has been developed to perform permeability relaxation measurements at constant ...
[EN] Magnetostrictive Fe-base amorphous wires spontaneously exhibit square-shaped hysteresis loops t...
Bitter method is most commonly observing way of the magnetic domain walls even though it is limited ...
Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Materials Science and Engineering, 20...