Your search keyword '"Philip L. Trouilloud"' showing total 2 results

1. A study of MiG head readout waveform asymmetry with magnetic force and Kerr Microscopy

Author

K. Sueoka, H. Setoh, B.E. Argyle, Shinji Takayama, R. Schafer, and Philip L. Trouilloud

Subjects

Materials science, Magnetic domain, Condensed matter physics, business.industry, Magnetic resonance force microscopy, Magnetic flux, Magnetic field, Condensed Matter::Materials Science, Magnetization, Optics, Remanence, Ferrite (magnet), Magnetic force microscope, business

Abstract

The cause of the readback waveform distortion in polycrystalline ferrite metal-in-gap (MIG) heads was investigated by using a magnetic force microscope (MFM) and a polarized optical microscope capable of microellipsometry for grain contrast and Kerr microscopy for domain contrast. It was revealed that, for high-asymmetry MIG heads, relatively large leakage of magnetic flux associated with complex multiple domains exists at remanence in the leading-side ferrite surface adjacent to the gap. The strengths of the magnetic flux and the magnetic domain states change irreproducibly when coil current is repeatedly applied. Such a remanent flux associated with the complex remanent state of magnetization distribution in the ferrite can cause an inhomogeneous flux coupling between the head and the recorded track, resulting in readback waveform asymmetry. >

Published

1992

2. Domain studies in single-crystal ferrite MIG heads with image-enhanced, wide-field, Kerr microscopy

Author

Philip L. Trouilloud, R. Schafer, and B.E. Argyle

Subjects

Materials science, Kerr effect, Magnetic domain, business.industry, Nucleation, Coercivity, Wide field, Electronic, Optical and Magnetic Materials, Optics, Microscopy, Ferrite (magnet), Electrical and Electronic Engineering, business, Single crystal

Abstract

The magnetic domain structure at the media-facing surfaces of the single-crystal ferrite MIG heads is investigated using the magnetooptical Kerr effect. Domain behavior depends strongly on the stress state and surface treatment of the head. The pole tips display coercive zig-zag domain walls, which are nucleated at the gap by write current pulses. For the samples studied, nucleation and motion of these walls are different between heads which exhibit small secondary pulses in the read-back signal and heads which do not. >

Published

1992