Metal working – Method of mechanical manufacture – Electrical device making
Reexamination Certificate
2000-06-09
2004-08-17
Chang, Richard (Department: 3729)
Metal working
Method of mechanical manufacture
Electrical device making
C029S603130, C029S603150, C029S603180, C360S125020, C360S125330, C360S313000, C360S317000, C216S022000, C216S066000
Reexamination Certificate
active
06775902
ABSTRACT:
FIELD OF THE INVENTION
This invention relates to thin film magnetic heads and in particular to an assembly and methods of making magnetic heads having narrow pole widths with high saturation threshold levels capable of writing on magnetic media with high areal densities and coercivity.
BACKGROUND OF THE INVENTION
A typical inductive thin film magnetic head comprises a first magnetic pole layer and a second magnetic pole layer with an electrical coil between the two pole layers. The two pole layers contact each other at one end at a back closure to form a continuous magnetic path, with a narrow transducing gap at the other end. The portions of the first and second poles separated by the transducing gap are designated respectively as the first and second pole tips. In order to write data with narrow track widths and high linear recording densities, it is necessary to provide a magnetic head with narrow pole tips. However, there are technical problems associated with fabricating a magnetic head with narrow pole tips. A key problem confronted during manufacture is the alignment of the two pole tips. Various methods have been suggested to solve this problem.
The magnetic head described above is called an inductive head. The inductive head can be combined with a data reading transducer to form a merged head.
FIG. 1
shows a prior art approach in which a magnetic head
2
is fabricated with a first pole tip
4
wider in lateral dimension than a second pole tip
6
. The wider first pole tip
4
tolerates a certain degree of misalignment during the deposition of the second pole tip
6
. In the magnetic head
2
, the width TW of the second pole tip
6
is intended to define the track width of the magnetic head
2
. However, the problem with this approach is that due to the larger width of the first pole tip
4
, magnetic flux fringing beyond the width of the second pole tip
6
is unavoidable. The fringing flux, such as flux lines F emanating from the second pole
6
to the first pole
4
as shown in
FIG. 1A
, would result in registering a data track
8
with a width W having ambiguous track boundaries, which seriously limit the track-to-track separations on the recording medium
10
.
Modern day storage products are now built with ever decreasing physical sizes and increasing storage capacities. Magnetic heads are fabricated on microscopically confined areas. To increase the sensitivity of the magnetic head, the number of coil windings can be increased. However, any increase in coil windings is restricted by the confined areas. Furthermore, the higher the number of coil windings, the higher is the resultant inductance attached to the magnetic head. A magnetic head with high inductance is sluggish in response to data writing current and incapable of operating at high frequency ranges.
Another approach to increase the writing sensitivity of the magnetic head is to increase the magnitude of the writing current. Higher writing current generates higher Joule heat which increases the burden of the magnetic heat formed in a confined space in respect to the heat dissipation. However, an overriding issue is the premature magnetic saturation encountered by the magnetic yokes in response to higher writing current.
FIG. 2
shows the hysteresis curve
12
of a magnetic material such as Permalloy (NiFe) which includes a high permeability slope of the curve
12
and low coercivity H
c
. Because of these characteristics, Permalloy is commonly used as the material for the magnetic yokes or tips of magnetic head.
FIG. 2A
is a fragmentary view of the conventional magnetic head
2
at the tip portion. When the writing current I passing through the coil
14
increases, the magnetic flux induced by the inductive coil
14
also increases. The magnetic flux which exerts coercive force on the magnetic yoke layers
16
and
18
also increases. For example, as shown in
FIG. 2
, when the coercivity exceeds 5 Oersteds, the magnetic yoke layers are fully saturated at 200 nanowebers and can no longer be responsive to any increase in writing current. Normally, magnetic saturation happens at the areas with the smallest physical dimensions. For instance, when magnetic saturation occurs, it first takes place at the first and second tip layers
4
and
6
and then slowly progresses to the areas with larger physical bulk, such as the yoke bodies
16
and
18
. With pole tips built smaller for the purpose of writing narrow data tracks, the problem of magnetic saturation is further exacerbated.
Magnetic heads with pole tips having vertically aligned sidewalls have been proposed. U.S. Pat. No. 5,452,164, Cole et al., entitled “The Thin Film Magnetic Write Head”, issued Sep. 19, 1995 discloses a magnetic head in which the vertically aligned sidewalls of the first and second pole tips are made possible by the process of ion milling through an overlying mask as a template. However, the magnetic head of Cole et at. does not address the magnetic saturation problem.
The problem of obscure data track boundaries written by a magnetic head and the problem of preventing the magnetic head from operating in premature saturation, when the head is built with a smaller physical size, need to be addressed. The problems are more intensified as storage products are now built with further reduced sizes and increased storage capacities. Data tracks written with ambiguous track boundaries seriously undermine track-to-track separations which in turn compromise the overall storage capacity of storage devices. A prematurely saturated magnetic head is incapable of operating at high frequency and is inept in performing high rate data transfer onto media with high areal densities. Accordingly, there has been a need to provide magnetic heads capable of writing data tracks with well defined track boundaries, yet made available at reasonable manufacturing costs.
SUMMARY OF THE INVENTION
It is an object of the invention to provide a magnetic head capable of writing narrow data tracks with high linear recording densities.
It is another object of the invention to provide a magnetic head having a high saturation threshold capacity and capable of performing high data rate transfer onto media with high coercivities and high areal densities.
According to this invention, a thin film magnetic head includes first and second pole tips separated by a nonmagnetic gap layer. The pole tips are made of a high magnetic moment material. The right side and left side walls of the first and second pole tips are vertically aligned with each other respectively. The side fringing flux of one pole tip to another is substantially reduced resulting in a magnetic head capable of writing data tracks with well defined boundaries. Furthermore, the possibility of the pole tips running into magnetic saturation is reduced because the pole tips, made of high magnetic moment material, are tolerant of high coercivity media.
The magnetic head of the invention can be fabricated as an inverted or a noninverted head. In either case, the aligned pole tips are first made by depositing a tri-layer sandwich having a gap layer between the first pole layer and the second pole layer on the substrate. The tri-layer sandwich is then etched away through a masking layer, thereby leaving at least a stack of layers formed on the substrate. The stack of layers constitutes the magnetic pole tip region of the magnetic head with aligned sidewalls for the pole tips. In accordance with the invention, the pole tips can be narrowly defined, thereby allowing the inventive head to write on magnetic media with narrow data track widths. The problem of premature magnetic saturation is avoided because the pole tips are made of high magnetic moment material.
REFERENCES:
patent: 4219853 (1980-08-01), Albert et al.
patent: 4853815 (1989-08-01), Diepers
patent: 5274521 (1993-12-01), Miyauchi et al.
patent: 5640753 (1997-06-01), Schultz et al.
Corona Carlos
Huai Yiming
Jensen William D.
Ravipati Durga P.
Thomas Mark D.
Chang Richard
Kallman Nathan N.
Western Digital (Fremont) Inc.
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