JPH04163708A - Magnetic head - Google Patents

Abstract

PURPOSE:To improve the correspondence for high-density recording and overwriting characteristics by constituting a magnetic film neighboring a conversion gap so that the saturation magnetic flux density of the film is higher than that of another magnetic film, and sharpening the distribution of a magnetic field and the regenerated waveform. CONSTITUTION:Of a magnetic film P11 and a magnetic film P12, the saturation magnetic flux density of the magnetic film P11 neighboring a conversion gap G is higher than that of a the magnetic film P12. A thickness T11 of the magnetic film P11 is thinner than a thickness T12 of the magnetic film P12. As a detailed example, when the magnetic film P12 is formed of NiFe, the magnetic film P11 is formed of CoNbZr. It is suitable that the ratio (T12/T11) between the thicknesses T11 and T12 is located within the range of 1<T12/T11<=25. Namely, of a plurality of the magnetic films P11 and P12, the saturation magnetic flux of the magnetic film P11 neighboring the conversion gap G is higher than that of the other magnetic film P12. Therefore, the magnetic flux is more readily concentrated toward the conversion gap G. Thus, the distribution of the magnetic field and the regenerated waveform are sharpened, and the magnetic field suitable for high-density recording and regeneration is obtained.

Description

[Detailed Description of the Invention] <Industrial Application Field> The present invention relates to a magnetic head, and relates to a magnetic head in which at least one of a pair of poles facing each other with a conversion gap in between, particularly the pole located on the media outlet end side, is connected to a plurality of magnetic heads. By creating a laminated structure of magnetic films and providing a non-magnetic film between the magnetic films,
This makes it possible to provide a magnetic head that sharpens the magnetic field distribution and reproduction waveform, supports high-density recording, and has improved override characteristics.

<Prior Art> As is well known, a magnetic head has a structure including a pair of poles facing each other with a conversion gap in between. FIG. 5 is a diagram showing the basic structure of a conventional magnetic head and the magnetic field distribution during writing.

PI and P2 are poles, G is a conversion gap, a is a medium outflow direction, and M is a magnetic recording medium such as a magnetic disk. L2 is the magnetic field distribution during writing, Mo is the magnetization reversal part, m
, , m2 indicate the magnetization direction, and 11 indicates the magnetization reversal region. Magnetization reversal region! is mainly determined by the magnetic field on the side of the pole on the medium outflow side, that is, the pole located at the rear when viewed in the medium outflow direction a (pole Pl in the illustrated case).

FIG. 6 is a diagram showing the magnetic head and its reproduction waveform L1. The reproduced waveform Ll is a waveform obtained when a signal recorded on a magnetic recording medium using a magnetic head having the pole structure and magnetic field distribution shown in Fig. 5 is reproduced by the same magnetic head, and the horizontal axis indicates the time axis. and the vertical axis shows the instantaneous value e and the maximum value E
The ratio with m (e/E m ) is expressed as a percentage. Lll indicates undershoot. P.W. indicates the pulse width at which (e/E m ) is 50%. The PWao value indicates the degree of sharpening of the reproduced waveform,
P W a. The smaller the value, the sharper the reproduced waveform L1,
As it gets bigger, it slows down.

<tWO to be Solved by the Invention> However, the above-described conventional magnetic head has the following problems.

(A) In order to cope with high-density recording, it is necessary to sharpen the reproduction waveform L1 and prevent mutual interference between adjacent pulses.

The degree of sharpening of the reproduced waveform is determined by PWS as described above.

Evaluate by value. The magnetic field distribution 2 of the magnetic head is mainly determined by the shape of the end faces of the poles P1 and P2.

In the conventional magnetic head, the magnetic field distribution cannot be made sharper than the thickness TA%Tml of the end face of the poles P, P2. In addition to the magnetic field distribution, the reproduction waveform is also slowed by the difference in coercive force Hc (coercive force distribution) that inevitably occurs in the magnetic film of the magnetic recording medium. For this reason, it has been difficult to further sharpen the reproduced waveform L2, which has been a major obstacle in achieving high-density recording.

(B) By reducing the thicknesses T^ and TB of the poles P, , P2, the reproduced waveform can be sharpened. However, Paul P.
, P, thickness TA%T! If l is made small, magnetic saturation occurs, the writing ability decreases, and the override characteristic deteriorates.

(C) As shown in Figure 6, the reproduced waveform is pole P,,P
Undershoot at the position corresponding to the edge of , l1%L
yields 12. Undershoots Lll and L12 appear particularly prominently in thin-film magnetic heads with thin poles. In a thin film magnetic head, unlike a bulk type magnetic head, the thickness of the end portions of the poles P1 and P2 as seen in the traveling direction a of the magnetic recording medium M is thin and finite. This is because pseudo pulses are generated by each end of P1%P2.

In the case of high-density recording, the presence of undershoots L and L12 increases the peak shift, which limits the read error margin or phase margin, and becomes a major hindrance to high-density recording.

Therefore, the i! i! The problem is to provide a magnetic head that solves the above-mentioned conventional problems, sharpens the magnetic field distribution and reproduction waveform, supports high-density recording, and improves override characteristics.

<Means for Solving Problem 31> In order to solve the above problems, the present invention provides a magnetic head having a pair of poles facing each other with a conversion gap in between, wherein at least one of the pair of poles is , is configured by laminating a plurality of magnetic films and a non-magnetic film disposed between at least one set of adjacent magnetic films, and among the magnetic films, the magnetic film adjacent to the conversion gap is different from other magnetic films. It is characterized by a higher saturation magnetic flux density than a film.

Effect> Among the plurality of laminated magnetic films, the magnetic film adjacent to the conversion gap has a higher saturation magnetic flux density than the other magnetic films, so the magnetic flux becomes more concentrated toward the conversion gap. Therefore, the magnetic field distribution and reproduction waveform are sharpened. Therefore,
High-density recording and playback becomes possible. In particular, when the pole on the media outflow end side is constructed by laminating multiple magnetic films, and the magnetic film adjacent to the conversion gap is constructed from a material with a higher saturation magnetic flux density than other magnetic films, the magnetization distribution on the medium The gradient of the magnetic field strength at the media outlet side, which determines the conversion gap, becomes steeper and better magnetic recording is obtained.It is desirable to form the magnetic film adjacent to the conversion gap so that it is thinner than other magnetic films. . By doing so, the concentration of magnetic flux is further promoted, and the magnetic field distribution and reproduction waveform are further sharpened.

The degree of concentration of magnetic flux can be controlled by selecting the magnetic properties and thickness of the magnetic film adjacent to the transducer gap film or other magnetic films to be laminated. This allows the magnetic field distribution and reproduction waveform to be sharpened in accordance with the frequency used.

Since the thickness of the tip of the entire pole is the thickness of the entire laminated structure that constitutes the pole, excellent penetration ability can be ensured.

Furthermore, since a nonmagnetic film is provided between the magnetic films, a sub-pulse is generated at a position close to the main pulse at the boundary between the non-magnetic film and the magnetic film during reproduction. Since the resulting reproduced waveform is a combination of the main pulse and the sub-pulses occurring at the boundary, the sub-pulses act in a direction that promotes sharpening of the main pulse. Therefore, the reproduced waveform is sharpened, the pwS value becomes smaller,
High-density recording becomes possible.

Furthermore, as a result of the sub-pulse generated at the boundary being combined with the main pulse, undershoot in the reproduced waveform is suppressed.

<Example> FIG. 1 is a diagram showing the structure of a pole portion of a magnetic head according to the present invention and its magnetic field distribution. It has a pair of poles PI and P2 facing each other with a conversion gap G in between. Of the pair of poles pHP2, at least the pole P1 on the medium outflow end side has magnetic films P, □ and magnetic wAP l 2 stacked thereon, and a non-magnetic film P13 between the magnetic films pHPI3.
It is laminated. Magnetic film Pl+ and magnetic till P
+ 2, the magnetic film Pl+ adjacent to the conversion gap G
The saturation magnetic flux density is larger than that of the magnetic film P12. Moreover, the thickness T11 of the magnetic film pH is the magnetic InI P +
It is thinner than the thickness Ti2 of No. 2. As a specific example, when the magnetic film P12 is made of NiFe, the magnetic film pH
is made of CoNbZr. The ratio of thickness Tl1%TI2 (T12/T++) is suitably in the following range: 1<TI2/Tll≦25.

The nonmagnetic film PUS contains at least one of Ti, Cr, and W as a main component. The nonmagnetic film PUS formed from these conductive metal materials becomes a film that is structurally stable with respect to the magnetic film pH and PI3. Thickness T of non-magnetic film P□3
For i3, approximately 50 to 3000 people is appropriate.

As described above, among the pair of poles PI and P2 facing each other with the conversion gap G in between, at least the pole P is constructed by laminating a plurality of magnetic films PI2 and a plurality of magnetic films. Conversion gap G among pH and PI2
Since the magnetic film P adjacent to P has a higher saturation magnetic flux density than the other magnetic films P12, the magnetic flux tends to concentrate as it moves toward the conversion gap G. Therefore, the magnetic field distribution 2 is sharpened as shown in FIG. 1, and the reproduced waveform L1 is sharpened as shown in FIG. 2, PW. The value becomes smaller.

Therefore, high-density recording and reproduction becomes possible. In particular, the pole P1 on the medium outflow end side is constructed by stacking a plurality of magnetic films pH and PI2, and the magnetic film pH adjacent to the conversion gap G is changed to the magnetic g! If it is made of a material with a higher saturation magnetic flux density than P + 2, the slope of the magnetic field strength on the medium outlet side, which determines the magnetization distribution on the medium M, becomes steeper, and favorable magnetic recording can be obtained.

When the thickness T11 of the magnetic film P1□ adjacent to the conversion gap G is made thinner than the thickness T12 of the magnetic film PL2, the concentration of magnetic flux is further promoted, and the magnetic field distribution 2 and the reproduced waveform L
1 is further sharpened.

The overall thickness of the end of pole P and closure is pole Pll,
Since the pH of the magnetic film constituting PI3 and the thickness of the entire stacked structure of PI2 (T +, + T I2) are the same, excellent writing ability can be ensured.

Furthermore, since there is a non-magnetic fij P 1s between the magnetic films pHPI3, as shown in FIG.
occurs at a position close to the main pulse L. Since the obtained reproduced waveform L+ is a combination of the main pulse L and the sub-pulse Ls, the sub-pulse L acts in a direction that promotes sharpening of the main pulse L.

Therefore, the reproduced waveform, PW, is sharpened. The value becomes smaller, enabling high-density recording.

Moreover, as a result of combining the sub-pulse Ls generated at the boundary with the main pulse L, undershoot that should appear in the reproduced waveform L1 is suppressed.

FIG. 3 is a diagram showing another embodiment of the magnetic head according to the present invention. In this embodiment, the pole P2 is also constructed by laminating a magnetic film P2, a magnetic film P22, and a nonmagnetic film PL3. The magnetic film P21 adjacent to the conversion gap G has a higher saturation magnetic flux density than the magnetic JIIP22. Further, the thickness Tz+ of the magnetic film P2I is thinner than the thickness T22 of the magnetic film P22. As in the case of the pole P, the thickness ratio (T22/T2+) is suitably in the range of 1<722/T21≦25. In the case of the embodiment shown in FIG. 3, the magnetic field distribution 2 and the reproduction waveform are sharpened at both poles PI and P2. The curved line in FIG. 3 is a reproduction waveform of a conventional magnetic head.

FIG. 4 is a sectional view of a transducer portion of a thin film magnetic head to which the present invention is applied. 1 is a base made of ceramic, 2 is a lower magnetic film, 3 is a gap film made of alumina, etc., 4 is an upper magnetic film, 5 is a coil film, and 6 is an insulating film made of organic insulating resin such as novolac resin. , 7 is a protective film made of alumina or the like.

The base 1 is a main body 1 made of Al2O, -Ti02, etc.
An insulating film 102 made of Al2O3 or the like is provided on the surface of 01,
A magnetic circuit is formed on this insulating film 102. The tips of the lower magnetic film 2 and the upper magnetic film 4 form poles P2, P, which face each other across a gap film 3 made of alumina or the like, and reading and writing are performed at these poles P, , P. The pole P and the pole P2 face each other with a conversion gap G formed by the gap wA3. Upper magnetic film 4
is the connecting portion 4 in the rear region opposite to the pole P1.
0 to the yoke portion 20 of the lower magnetic film 2. The coil @5 is formed to spiral around the coupling portion 40.

The lower magnetic film 2 includes a magnetic film P21, a magnetic film P22, and a non-magnetic II! It has a structure in which P23 is laminated.

The magnetic film P21 adjacent to the gap lj3 is made of CoNbZr.
The magnetic film P2□ is made of NiFe. These magnetic @P23, P22 and non-magnetic film P23 are provided extending to the pole P2. The magnetic film P21 adjacent to the conversion gap G has a thickness equal to that of the magnetic film P2.
It is thinner than 2. The non-magnetic film P23 is made of Ti.
It is formed as a membrane.

The upper magnetic film 4 has a structure in which a magnetic film pH, a magnetic film P12, and a non-magnetic film PU are laminated.

The magnetic layer 11j P r 1 adjacent to the gap film 3 is Co
It is made of NbZr, and the magnetic film PI2 is made of NiFe. These magnetic film pH, PI2 and non-magnetic OI
P r s is provided extending to the pole P1.

The magnetic film pH adjacent to the conversion gap G has a thickness of 1
1i P I It is thinner than the thickness of 2. The nonmagnetic films P and s are formed as Ti films.

In FIG. 4, magnetic FA (Pll, P, 2), (P21,
P, 2) and non-magnetic films P13, P23 are the upper magnetic film 4
Although it is provided over the entire lower magnetic film 2, it may be provided only in the regions of the poles PI and P2. Further, although the description has been given using a thin film magnetic head as an example, the present invention can be similarly applied to, for example, a monolithic magnetic head, a composite magnetic head, and the like.

<Effects of the Invention> As described above, according to the present invention, the following effects can be obtained.

(a) At least one of a pair of poles facing each other with a conversion gap in between is configured by laminating a plurality of magnetic films, and among the plurality of magnetic films, the magnetic film adjacent to the conversion gap is Since the saturation magnetic flux density is higher than that of other magnetic films, the magnetic field distribution and reproduction waveform can be sharpened, and a magnetic head suitable for high-density recording and reproduction can be provided.

(b) By selecting the magnetic properties and thickness of the magnetic film adjacent to the conversion gap film or other magnetic films to be laminated,
It is possible to provide a magnetic head that can sharpen the magnetic field distribution and reproduction waveform according to the frequency used.

(C) It is possible to provide a magnetic head for high-density recording with sharpened pole magnetic field distribution and reproduction waveform, secure writing ability, and excellent override characteristics.

(d) Since there is a non-magnetic film disposed between at least one set of adjacent magnetic films, the sub-pulses generated at the boundary between the non-magnetic film and the magnetic film during reproduction are directed in a direction that promotes sharpening of the main pulse. It acts on Therefore, the reproduced waveform is sharpened and the PW
A magnetic head having a small 5° value and suitable for high-density recording can be provided.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing the structure of the pole part of the magnetic head according to the present invention and its magnetic field distribution, FIG. 2 is a diagram showing the structure of the pole part and the reproduction waveform, and FIG. Figure 4 is a cross-sectional view of the transducer part of a thin-film magnetic head to which the present invention is applied, and Figure 5 is a diagram showing the basic structure of a conventional magnetic head and its reproduction waveform during writing. Diagram YS6, which is a diagram showing magnetic field distribution, is a diagram showing a conventional magnetic head and its reproduction waveform. P, +, P2...Pole pit, P2+...Magnetic film P22, P22...Magnetic film G...Conversion gap Y: 1121

Claims (5)

[Claims] (1) A magnetic head having a pair of poles facing each other with a conversion gap in between, wherein at least one of the pair of poles is arranged between a plurality of magnetic films and at least one set of adjacent magnetic films. What is claimed is: 1. A magnetic head comprising a stack of non-magnetic films, wherein a magnetic film adjacent to the transducing gap has a higher saturation magnetic flux density than other magnetic films. (2) The magnetic head according to claim 1, wherein the nonmagnetic film contains at least one of Ti, Cr, and W as a main component. (3) The magnetic head according to claim 1 or 2, wherein the magnetic film adjacent to the transducing gap is thinner than other magnetic films. (4) The magnetic head according to claim 1, 2 or 3, wherein the pole having the plurality of magnetic films and the non-magnetic film is a pole on a medium outflow end side. (5) Claims 1 and 2 are characterized in that the pole and the conversion gap are formed of a thin film.
, 3 or 4.