KR100234186B1 - Planar type composite magnetoresistive recording/reproducing head with dual gap - Google Patents

Abstract

A planar combined magnetoresistive read / write head having a dual gap includes a write induction head separated from and integrated with each other and a magnetoresistive head for read. The head has an air bearing surface oriented parallel to the plane of the substrate. The recording-purpose induction head includes a writing core having a terminal magnetic pole and a writing gap formed on the air bearing surface. The readout magnetoresistive head includes a readout core having a tip magnetic pole, a read gap formed on the air bearing surface, and a non-magnetic gap recessed from the air bearing surface and bridged by the magnetoresistive element. The reading and writing gaps are separated from each other by a shared magnetic pole, which functions in common as the terminal magnetic pole of the reading magnetoresistive head and the leading magnetic pole of the writing inductive head. Shared stimulation has a stimulating tip on the air bearing surface, which has a gap for reading along the track width and a different width for the portion near the writing gap. The width of the end portion of the stimulation tip proximate to the read gap is less than the width of the tip portion of the stimulation tip proximate the fill gap to provide high track resolution and suppress lateral readout. Furthermore, the width of the termination portion is equal to the width of the tip stimulus, and the width of the tip portion is equal to the width of the termination stimulus.

Description

Planar combination magnetoresistive read / write heads with dual gaps

The present invention relates to a magnetic read / write head, and more particularly to a planar combination magnetoresistive read / write head having a separate read write gap.

Magnetoresistive (MR) heads are attractive devices for magnetic recording due to their high readout sensitivity, readout amplitude, and independent read speed. A combined magnetoresistive (MR) head including an induction write head integral therewith away from the magnetoresistive head is known. Typically, the combined MR head has an induction write gap that is longer in length than the read gap and a write track width that is wider than the read track width. The level of recording medium noise in magnetic recording is generally greater at the corners of the recorded tracks than at the center of the tracks. Therefore, it is desirable to provide a magnetic head having a reading width that is slightly narrower than the writing track width. The narrow read head detects information only from the center of the track when positioned towards the center of the recorded track. Providing a wider track width also guarantees complete erasure of old data and rewriting of new tracks which avoids later reading of old data from track edges due to servo tracking errors Which is sufficiently wide. This contributes to good overlapping performance. Separation of the read / write head in the combinatorial head makes it possible to individually optimize the read and write gap and the stimulus portion. However, the use of a combination head having a read actuator and a write gap with a rotary actuator and spaced apart from a disk drive with a high track density causes a misalignment of the read head relative to the write head as a function of the write gap for the read gap distance do. The improvement in track resolution in a combined head with dual gaps is followed by a reduction in the gap to gap spacing.

The number of MR head designs can be divided into two main groups, which are the vertical head and the flat head. In the vertical MR head, the plane of the MR element is perpendicular to the plane of the magnetic medium. In a vertical MR head without a flux guide, one corner of the MR element is exposed to the air bearing surface (ABS) of the head. An example of this is disclosed in U.S. Patent No. 3,908,194 (Sep. 9, 1975). tea. It is shown in Romanki's "Integrated magnetoresistive readout, induction, and batch production magnetic head". At the air bearing surface, the magnetoresistive element is vulnerable to mechanical wear, vulnerable to chemical corrosion at the open surface, and vulnerable to electrical shorting between the element and the magnetic medium. This vertical MR head also has an asymmetric cross-track profile that complicates the servo design. One of the disadvantages of a vertical MR head is the high cost due to numerous precise machining such as lapping or polishing in manufacturing technology. Some of these problems can be alleviated by adding an additional magnetic structure that allows the MR sensor to be recessed from the air bearing surface and to maintain signal flux con- ductivity from the open surface to the MR element.

In known planar silicon head designs, the heads have separate reading and writing gaps that can be optimized individually. For example, in U.S. Patent No. 5,434,733 (July 17, 1995) Bless you. Hesterman and M. K. Batakariya, "planar heads with separate read and write gaps ". The write-in gap of the head includes a write gap shunt so as not to affect the write characteristic sensitively and to suppress the reading of the signal over the write gap. The MR element is recessed from the air bearing surface and positioned across the read gap to detect magnetic transitions in the recording medium proximate to the read gap. The arrangement in which the MR elements are displaced from the air bearing surface solves the problem of shorting, excessive wear and corrosion of the MR element and is related to the asymmetrical nature of the transverse track response of the double gap MR head in a vertical, Eliminates transverse track asymmetry. However, in design, the MR element is strongly influenced by the write magnetic flux and has reduced efficiency during writing due to signal magnetic flux leakage through the MR element and high resistance of the side gaps. In addition, the head has reduced track resolution due to the large read gap to the spacing of the write gap. The configuration process for the planar combination head has the same advantages with respect to the inductive version of the planar silane cone head, which is described in U.S. Patent No. 4,949,207 (1990, blood. Is described in "planar-structured thin-film magnetic heads ".

It is therefore a principal object of the present invention to provide a planar magnetically coupled read / write head that enhances sensitivity and stabilizes the output characteristics of the magnetoresistive element by suppressing the write head in the readout portion of the combination head.

1 is a cross-sectional view of a specific embodiment of a planar combination magnetoresistive read / write head in accordance with the present invention;

Figures 2a and 2b are plan views of two examples of the planar combination magnetoresistive read / write head shown in Figure 1 from an air bearing surface.

3 is a cross-sectional view of another embodiment of a planar combination magnetoresistive read / write head having dual gaps according to the present invention.

4 is a cross-sectional view of another embodiment of a planar combination magnetoresistive read / write head having dual gaps in accordance with the present invention having dual flux interactions between the coil and the write core.

5 is a schematic plan view of a coil of a planar combination magnetoresistive read / write head having a dual gap shown in FIG. 4, which has dual flux interaction with the write core.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

11. Substrate 12. Air bearing surface

17. Reading Core 19. Reading Gap

20. Non-magnetic gap 21. Magnetoresistance element

22. Shared Stimulation 23. Stimulation Tips

In one embodiment of the present invention, the planar combination magnetoresistive read / write head includes a write induction head and a magnetoresistive head for readout integrated with each other separated from each other. The planar combination magnetoresistive head has an air bearing surface oriented parallel to the plane of the substrate. The recording inductive head includes a readout core having a writing gap and a trailing pole formed at the air bearing surface. The readout magnetoresistive head includes a reading pole having a leading pole and a read gap formed at the air bearing surface, and a non-magnetic gap recessed from the air bearing surface, which is bridged by the magnetoresistive element . The reading and writing gaps are separated from each other by a shared magnetic pole, which functions in common as the terminal magnetic pole of the reading magnetoresistive head and the leading magnetic pole of the writing inductive head. The shared stimulus has a stimulating tip at the air bearing surface, which has a gap for reading along the track width and a portion of different width near the gap for writing. In order to provide high track resolution and to suppress lateral readout, the end portion width of the stimulation tip proximate to the read gap is less than the tip portion width of the stimulation tip proximate the fill gap. Furthermore, the width of the end portion is equal to the width of the tip stimulus, and the width of the tip portion is equal to the width of the end stimulus.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.

Figure 1 shows a specific embodiment of a planar combination magnetoresistive (MR) readout and write head according to the present invention. The head is formed on the substrate 11 and has an air bearing surface (ABS) 12 oriented parallel to the surface of the substrate 11. The planar combination head includes two heads, a write inducing head and a read MR head, which have a common magnetic pole 22 in common. The shared magnetic pole 22 performs two functions, which is a function of the trailing pole of the read-out MR head and the leading pole of the write-inducing head.

The MR head for reading includes a readout core 17 having a leading magnetic pole 18 and a reading gap 19 which is formed in the air bearing surface 12 and is connected to the leading magnetic pole 18 and the shared magnetic pole 22, Respectively. In addition to the read gap 19, the read MR head includes a non-magnetic gap 20, which is recessed from the air bearing surface 12 and bridged by the MR element 21. The plane of the MR element 21 is oriented parallel to the plane of the ABS 12. The concave portion of the non-magnetic gap 20 prevents the MR element 21 from being mechanically abraded, chemically corroded and shorted to magnetic media. In addition, the concave portion of the upper portion of the readout core 17 reduces the length of the leading magnetic pole 18 along the track, and as a result, improves the linear resolution of the reading MR head. An output signal is detected and a capacitor lead 24 supplying a bias current to the MR element 21 is deposited in direct contact with the edge portion of the MR element 21. [ The MR element 21 and the conductor lead 24 are electrically isolated from the read-out core 17 by an insulating layer (not shown).

The MR element 21 is provided with means for longitudinal and transverse bias not shown in FIG. The longitudinal bias is at a sufficient level for the MR element 21 in a single domain state and thus suppresses Barkhausen noise in the output signal. The lateral bias is produced at a level sufficient to hold the MR element 21 in a linear response mode. The design of the means for the longitudinal and transverse bias of the MR element 21 is not part of the invention. This will be appreciated by those of ordinary skill in the art. The spin valve or giant magnetoresistive form of the MR element 21 may be used to obtain a larger output signal.

The recording-purpose induction head includes a recording core 13 and a coil 16 having a termination magnetic pole 14 and a writing gap 15, which are formed around the recording core 13. The upper portion of the recording core 13 is recessed at a distance of 1 to 5 占 퐉 from the air bearing surface 12 so as to improve linear resolution of the recording head and prevent mechanical wear of the recording core. 1, the coils 16 are flux-interacted with the recording core 13 formed around the terminating magnetic pads 25 of the recording core 13. In this particular embodiment, This measure prevents shorting of the signal magnetic flux during writing through the MR element 21 and as a result a strong magnetic flux does not degrade the magnetic state of the MR element 21, It is sensitive to the noise ratio.

1, the shared magnetic pole 22 is disposed between the reading core 17 and the recording core 13 and performs two functions, one of which is the end of the reading MR head And the other is the tip stimulus of the recording-use induction head. Shared magnetic poles 22 include a stimulation tip 23 formed at air bearing surface 12. The stimulation tip 23 has two portions. One end portion near the read gap 19 and the other end portion near the write gap 15. The width of the end portion is smaller than the width of the tip portion of the stimulation tip 23 in the width direction of the track so as to suppress the influence of the side readout effect. The width of the termination portion is about 0.6 to 0.9 times the width of the tip portion. Furthermore, the width of the end portion is equal to the width of the tip end magnetic pole 18, and the width of the tip end portion is equal to the width of the end termination magnetic pole 14. The stimulating tip 23 may have a different shape. Two shapes for the geometry of the stimulation tip 23 are shown in Figures 2A and 2B. The length of the stimulation tip 23 along the track is 2.5 to 4 占 퐉.

Another embodiment of a planar MR head according to the present invention is given in Fig. This embodiment differs from the embodiment illustrated in Figure 1 by the location of the non-magnetic gap 20 and the MR element 21. [ In the embodiment shown in Fig. 3, the non-magnetic gap 20 is formed in the bottom portion of the readout core 17, which is opposed to the air bearing surface 12. The position of the non-magnetic gap 20 has a considerable influence on the sensitivity of the MR head for reading.

Another embodiment of a planar combination MR head according to the present invention is shown in Fig. This embodiment differs from the embodiment shown in Fig. 1 by the position and design of the coil 16, which has two interactions with the recording core 13. The coil 16 is formed around the end magnetic pad 25 and the common magnetic pole 22. This position of the coil 16 provides a recording head with improved sensitivity and reduced inductance during the writing process. A schematic view of the coil from the air bearing surface of the embodiment shown in Fig. 4 is shown in Fig. 5 along with the orientation of the interrogation current and the position of the coil contact pad 28. Fig.

The embodiment of the planar MR head shown in Figures 1, 3 and 5 is made of the same material. The read core 17, the write core 13, and the shared magnetic pole 22 are made of NiFe film. They may also be made of other soft magnetic films such as FeAlSi, CoZr, CoMoZr, CoNbZr, FeN, FeAlN, and the like. The MR element 20 is made of a NiFe film having a thickness of 150 to 400 ANGSTROM and the conductor lead 25 is made of a three layer structure of Ta / Au / Ta. The coil 16 is made of a Cu film having a thickness of 1.5 to 4.0 mu m. The coil 16 is electrically isolated from the recording core 13 by an insulating layer made of Al ₂ O ₃ and sputtered photoresist having a hardened backside. The MR element 21 and the conductor lead 25 are isolated from the read core 17 by an insulating layer made of a sputtered Al ₂ O ₃ film.

The method of manufacturing a planar MR head is not part of the present invention. As will be appreciated by those skilled in the art, the MR head can be made by known thin film fabrication techniques in a manner similar to making an integrated circuit chip. Such fabrication processes include the deposition of a thin film layer on a substrate and the appropriate shaping of the monolayer by suitable techniques such as selective etching and photolithography.

Although the present invention has been shown and described with reference to the preferred embodiments thereof, it will be understood that various modifications and equivalent embodiments may be made by those skilled in the art. Therefore, the true scope of protection of the present invention should be defined by the appended claims.

Claims (7)

Board, An air bearing surface oriented parallel to the plane of the substrate, A write core having a trailing pole and a write gap formed at the air bearing surface, and a coil formed around the write core, A readout core having a leading end magnetic pole and a read gap formed on the surface of the air bearing, a nonmagnetic gap recessed from the air bearing surface, and a magnetoresistive element disposed across the nonmagnetic gap, , A magnetic pole of the reading magnetoresistive head and a magnetic pole of the read magnetic pole head for writing are separated from each other by the writing gap from the leading magnetic pole and separated from the terminating magnetic pole by the writing gap, And a shared pole used to function commonly as a leading pole of the induction head. The flat combination magnetoresistive read / write head of claim 1, wherein the upper portion of the readout core and the upper portion of the write core are concave from the air bearing surface. 3. The apparatus of claim 2, wherein the shared pole comprises a pole tip formed at the air bearing surface and having a tip portion and a tip portion, wherein the tip portion and the tip portions have different widths along the track width Combination magnetoresistive read / write heads. 4. The flat combination magnetoresistive read / write head of claim 3, wherein the width of the end portion of the pole tip proximate the read gap is less than the width of the tip portion of the pole tip proximate the fill gap. 5. The magnetic sensor according to claim 4, wherein the width of the end portion of the pole tip is equal to the width of the tip pole, and the width of the tip portion of the pole tip is equal to the width of the pole tip magnet Read / write heads. 6. The flat combination magnetoresistive read / write head of claim 5, wherein the coil is formed around an end magnetic pad of the write core. 6. The flat combination magnetoresistive read / write head of claim 5, wherein the coil is formed around the shared magnetic pole and the termination magnetic pad to provide two flux interactions therebetween.