DE3544883A1 - Thin-film magnetic head for the perpendicular magnetisation of a corresponding recording medium - Google Patents

Abstract

The thin-film magnetic head for a recording medium to be magnetised perpendicularly (vertically) has two magnet legs of laminated construction, the magnet poles of which are arranged one behind the other, seen in the (relative) direction of movement of the head, forming a gap of predetermined width. It is intended with this head to be able to perform a read and write function with high efficiency in each case. According to the invention, for this it is provided that the leading magnet leg (9), seen in the direction of movement (v), has at least two magnetic layers (9a, 9b) of different saturation magnetisation (Ms1, Ms2), the magnetic layer (9b) of the comparatively smaller saturation magnetisation (Ms2) bounding the gap and, in the write function, being driven into the saturation by a corresponding write current (I) as far as into the region of the assigned magnet pole (P1), and that the trailing magnet leg (10), the pole face (F2) of which is to be at least as large as the pole face (F1) of the leading magnet leg (9), contains at least one magnetic layer (10a) of comparatively greater saturation magnetisation (Ms3). <IMAGE>

Description

The invention relates to a thin film magnet Head with layered structure on a non-magne table substrate for a recording medium with a magnetizable storage layer is provided in which along a track information by vertical (vertical) magnetization of the storage layer are to be ascribed which magnetic head the magne table flux leading, ring head-like magnetic Has guide body with two magnetic legs,

• - The predetermined saturation magnetisie from material persist,
• - Their magnetic poles facing the recording medium seen in (relative) direction of movement of the head are arranged one behind the other, with a gap predetermined width is formed, and
• - The space outside the pole area limit through which the turns of one Extend write and / or read coil winding.

Such a magnetic head is e.g. from EP 00 12 910 Al refer to. This head is for storing In formations based on the principle of vertical magnets provided for. This principle is generally knows (see e.g. "IEEE Transactions on Magnetics", vol. MAG-16, no. 1, Jan. 1980, pages 71 to 76, or vol. MAG-20, no. 5, Sept. 1984, pages 657 to 662 and  675 to 680). The for this often as verti kale magnetization principle to be provided Recording media can be in the form of a rigid magnet storage disks, flexible single disks (floppy discs) or magnetic tapes. These media point out because at least one magnetizable storage layer predetermined thickness, which is a magnetic aniso tropical material especially made of a CoCr alloy contains. The axis is the so-called easy one Magnetization of this layer perpendicular to the surface of the medium. Using a special magnet heads can then track the individual In along a track formations as bits in consecutive Ab cut by appropriate magnetization of the Storage layer can be registered.

The for the principle of longitudinal magnetization known combined write and read magnetic heads however, cannot easily be used for a vertical Magnetization are taken over. When using this Heads whose magne formed from magnetic legs table guide body generally a ring head-like Has shape, you can also with the principle the magnet sought for vertical magnetization flow to a closed circle with achieve low magnetic resistance. However is it is difficult at high bit densities and therefore ent speaking small width of the so-called air gap, between those facing the recording medium Magnetic poles of the ring head is formed on generate sufficiently strong writing field.

One is therefore generally seen to be responsible for the principle of vertical magnetization special  To develop read / write magnetic heads. The structure such a head goes e.g. from the beginning called EP-Al. This known magnetic head has to guide the magnetic flux one on one non-magnetic substrate applied conductive body on. This guide body consists of a magnetic Material of predetermined saturation magnetization such as e.g. made of a special NiFe alloy (e.g. "Permalloy" - trademark of "Bell Telephone Manu facturing Comp. "). It is ge by two magnetic legs forms whose facing the recording medium Magnetic poles seen in the direction of movement of the head one after the other and with a predetermined small gap are far apart. To the area of Magnetic poles join an area of the head in which the magnetic legs on a larger mutual Distance are guided. This way sufficient between the two magnetic legs wide space through which the turns extend a write and read coil winding. Like this probably for the write function as well as for the read The function of this magnetic head is that of a ring head Exploited the shape of its magnetic guide.

The individual parts of this magnetic head are in Thin film technology on the flat back of the sub strates upset. This technique is for writing / Read magnetic heads generally known (compare e.g. "Fine work technology and measurement technology ", 88th vol., issue 2, March 1980, pages 53 to 59 or "Siemens magazine", Volume 52, Issue 7, 1978, pages 434 to 437). Problem is matically with such thin-film magnetic heads the generation of sufficiently large write fields under maintaining high resolution at the same time  Read. These two demands are in themselves against of an additional nature, since generally high magnetic fields large gap widths require, while a high Resolution, i.e. a small bit shift at high bit densities only with small gap widths can be achieved (see e.g. "IEEE Transactions on Magnetics ", vol. MAG-19, no. 5, Sept. 1983, pages 1617 until 1619). In addition, with a magnetic head for vertical recording, the writing field if possible be asymmetrical to the vertical component of this Field at the trailing edge of the in Be seen direction of movement to the rear magnetic pole lift and the vertical component opposite Polarity at the leading edge of the front, the Weaken magnetic pole facing the substrate.

The object of the present invention is the thin Magnetic film head of the type mentioned above going to improve that with him a writing and Reading function with relatively high Efficiency based on the principle of the vertical magnet tization is possible. The mentioned Requirements regarding large writing fields and high Resolving power at least largely taken into account be.

This object is achieved in that

• - The leading magnet seen in the direction of movement pour out at least two magnetic layers Materials of different saturation magnetization has, wherein the magnetic layer from one Material with the comparatively smaller satti magnetization limits the gap and at Write function due to one in the coil winding flowing write current up to the range of  ordered magnetic poles into magnetic saturation is driven
• - The trailing magnetic leg at least one contains magnetic layer, the material of which Has saturation magnetization that is greater than the comparatively smaller saturation magnetization the magnetic layer delimiting the gap running magnetic leg, and
• - those of the magnetic pole of the trailing magnet leg area is at least as large like the area of the magnetic pole of the leading magnet thigh.

In the leading magnetic leg is consequently at Write the magnetic layer with the comparatively smaller saturation magnetization is quite right low write currents saturated. Another thing rise of the write current then causes the Magnetic layer of this leg with the larger one Saturation magnetization additionally magnetic flux records and so practically only this part of the preliminary fenden magnetic leg together with the trailing Magnetic arm is effective for a write function. There the magnetic layer in the leading magnetic leg with the greater saturation magnetization by the Magnetic layer with the comparatively smaller one Saturation magnetization is separated from the gap, becomes the effective gap width when writing advantageous to the thickness of the magnetic layer with the correspondingly smaller saturation magnetization expanded. Furthermore, since the effective when writing Pole area of the leading magnetic leg smaller than that of the trailing magnetic leg, can be hence the desired asymmetry of the writing field to reach. When reading, however, are from  Leaving storage layer of the recording medium Magnetic fields are known to be relatively low, so that the magnetic layer of the leading magnetic leg with the smaller saturation magnetization or not at least not completely down to the magnetic Are able to drive satiety. This means that in this leg practically only with this layer Reading function is exercised. The effective gap width between this layer and the trailing magnet thigh is therefore less than when writing. So with such a configuration of the magnet on the one hand, an at least asymmetrical field course of the writing field with sufficient gap to generate wide. On the other hand, you can choose between the Magnetic poles due to the resulting reading a relatively small gap width accordingly gain sharp waveform. The advantages of invent In accordance with the design of the magnetic head consequently in that with the adjustment of the effective Gap width of its magnetic poles to that exerted Function a correspondingly high efficiency in both Functions is achieved.

Advantageous embodiments of the invention Magnetic head emerge from the subclaims.

To further explain the invention reference is made to the Drawing referred to in the figure, a Ausfü Example of a magnetic head according to the invention is illustrated schematically.

The magnetic head shown only partially as a longitudinal section in the figure is based on known ring-head-like embodiments with a layer-by-layer structure, as developed for the principle of vertical (vertical) magnetization (see, for example, the EP-A1 mentioned at the beginning) . With the magnetic head generally designated 2 , both a write and a read function should be performed. This head is located on a flat side of a substrate 3 , which forms the front or in particular the back of a common element, also referred to as a missile, and which is not shown in the figure. The magnetic head is to lead relative to a known recording medium M in f low altitude, wherein the relative loading movement direction of the recording medium of the magnetic head is indicated by a V designated arrowed line with respect to. Which is designed between the at least one minde Flugkufe, the recording medium M underside facing 4 of the substrate 3 and the recording medium M fly height adjusting f be carrying, for example, only a few tenths of a micrometer. The recording medium, for example a magnetic disk, has a storage layer 6 , the material particles of which are oriented vertically (vertically) and in particular consist of a CoCr alloy. The storage layer 6 is generally arranged on at least one further layer 7 , for example made of a special NiFe alloy.

The magnetic head 2 contains a ring head-like guide body 8 guiding the magnetic flux with two magnetic legs 9 and 10 . These legs are largely and in particular in the area of the recording medium M facing, magnetic poles P ₁ and P ₂ forming end pieces 11 and 12 at least approximately perpendicular to the surface of the recording medium. Between them there is an air gap 13 with an advantageously small longitudinal, ie pointing in the direction of movement v of the magnetic head, width w of less than 1 μm, in particular less than 0.5 μm. In a middle Be rich 15 of the magnetic guide body 8, the distance between the two magnet legs w is extended 9 and 10 with respect to this gap by, for example, the out clearly the direction of movement v rear, w ie trailing magnet leg 10 to a larger distance 'relative to the front, just formed and the substrate 3 facing magnetic leg 9 leads. Outside this area 15 is on the recording medium M facing away from the guide body 8 of the magnetic leg 10 in a known manner in a connec tion area 16 to the magnetic leg 9 , so that this results in the ring-like shape of the guide body 8 . Through the between the two magnet legs 9 and 10 in the central region 15 formed out space 17 extends at least one flat coil winding 18 , which can serve both as a writing and reading coil. This winding, indicated in the figure only by a single conductor turn 18 a , generally has one or more layers with a relatively large number of turns. A generally large write current I can flow through them.

The magnetic leg 9 running in the relative direction of movement v has at least two magnetic layers 9 a and 9 b at least in the region of its end piece 11 . According to the invention, materials with different saturation magnetization Ms should be chosen for these magnetic layers. Alloys such as "permalloy", amorphous CoZr or CoHf alloys or other known binary or ternary amorphous or crystalline alloys are particularly suitable for this. The larger saturation magnetization should advantageously have a value above 1000 kA / m, while the value of the smaller saturation magnetization is, for example, below 1000 kA / m. Materials are preferably selected whose saturation magnetizations differ by at least a factor of 1.2. "Permalloy" has, for example, a saturation magnetization in the order of 800 kA / m, while the saturation magnetization of the amorphous materials mentioned is in the order of 1000 to 1200 kA / m. In the leading magnetic leg 9 , the arrangement of the individual magnetic layers should now be made so that the magnetic layer 9 b of the material with the comparatively smaller saturation magnetization Ms ₂ limits the gap 13 , while the other magnetic layer 9 a of the material with the larger Saturation magnetization Ms ₁ facing the substrate 3 . In contrast to the persist current magnetic leg 10 is generally of a uniform material and having as at least a magnetic layer, the material supply magnetizing a Saetti Ms ₃ which is greater than the relatively smaller saturation magnetization Ms ₂ of the layer 9 b of the preceding magnetic limb 9 is. For example, Ms ₃ = Ms ₁. According to the Darge presented embodiment, it is assumed that the magnetic leg 10 is constructed at least in the region of its Polend piece 12 from two such magnetic layers 10 a and 10 b . These layers can optionally also consist of materials of different saturation magnetizations, but these saturation magnetizations should be larger than Ms ₂.

Since in general with the trailing magnetic leg 10 an overwriting of the leading magnetic leg 9 information must be made, it is also provided in the magnetic head 2 according to the invention that the area occupied by the magnetic pole P _{1 of} the magnetic leg 9 surface F ₁ parallel to Storage medium M is at most equal to the corresponding area F _{2 of} the magnetic pole P _{2 of} the trailing magnetic leg 10 . For this purpose, it is assumed in the selected exemplary embodiment that the thicknesses d _a , d _b and d _a 'of the magnetic layers 9 a and 9 b and 10 a are approximately the same. If necessary, you can also choose different thicknesses. The respective thickness is understood to mean the expansion of the corresponding layer in the direction of movement v . However, for example, the magnetic layer 10 b of the trailing magnetic leg 10 should have a thickness d _b 'which is substantially greater than the thickness d _a ' of the adjacent, the gap 13 delimiting magnetic layer 10 a . Accordingly, the following applies to the partial areas F _a or F _b or F _a 'or F _b ' of the respective pole faces F ₁ or F ₂ of the layers 9 a , 9 b , 10 a and 10 b : F _a = F _b = F _a ′ < F _b ′, where F _a + F _b = F ₁ and F _a ′ + F _b ′ = F ₂ . F _b ′ is preferably at least twice as large as F _a ′, ie the following then applies: F ₂ , (3/2) · F ₁ . It is particularly advantageous if at least twice the size of F _{1 is} provided for F ₂ .

When writing by appropriate excitation of the coil winding 18 , the magnetic layer 9 b is saturated even at relatively small write currents I , where with increasing write current the saturated zone extends from the area of the coil winding 18 to the magnet pole P ₁ . Since then this layer can no longer absorb an additional flow, a further increase in the write current I leads to the fact that its neighboring magnetic layer 9 a made of the material with the substantially larger saturation magnetization Ms ₁ together with the magnetic layers 10 a and 10 b of the after Magnet leg 10 exercises the write function. Consequently, the effective gap length designated w _s during writing is determined by the distance between the magnetic layer 9 a and the magnetic layer 10 a . During reading, however, the layer of the memory 6 of the recording medium M escaping magnetic fields are known to be relatively small, so that these are capable of the magnetic layer 9 b of the material with the lower saturation magnetization Ms ₂ not in the saturation drive. Consequently, the reading function is also carried out with this magnetic layer. That is, the effective gap width in reading corresponds to the specific width w of the gap 13 and is therefore advantageous over the gap width _s w by the thickness d _b of the magnetic layer 9 b smaller.

As can also be seen from the figure, each of the magnetic legs 9 and 10 , or at least the trailing leg 10 , can be seen with an additional, relatively thick magnetic layer 9 c and 10 c outside the area occupied by the pole end pieces 11 and 12 , respectively . These layers cover in particular the area 15 with the coil winding 18 . These layers can advantageously be used for the desired asymmetry of the field profile of the writing field to be generated with the magnetic guide body 8 . If necessary, with only the magnetic layers 9 a , 9 b , 10 a , 10 b pointing and thus asymmetrically constructed magnetic head, no sufficient emphasis can be placed on the magnetic field generated by the trailing magnetic leg 10 , since in general the usable magnetic flux through the magnetic pole P ₂ is lowered because of the higher magnetic resistance of its comparatively longer magnetic leg. In order to compensate for this reduction, the cross-sectional area of the magnetic leg 10 in the region 15 can, for example, be chosen to be larger than the cross-sectional area of the magnetic leg 9 . For this purpose, it is assumed according to the illustrated embodiment that the thickness d _{c of} the additional magnetic layer 9 c of the magnetic leg 9 running before is chosen to be smaller than the corresponding thickness d _c 'of the additional magnetic layer 10 c of the trailing magnetic leg 10 .

Instead of the predetermined dimensions of the thicknesses of the individual magnetic layers or in addition to this, an asymmetry of the writing field is also possible because one builds up the additional layers 9 c and 10 c from materials of different saturation magnetization Ms ₂ 'or Ms ₃', the Saturation magnetization Ms ₃ 'of layer 10 c is greater than the saturation magnetization Ms ₂' of layer 9 c is selected. According to the illustrated Ausführungsbei was game assumed that for the magnetic layers 9 c and 10 c, the same materials as those of them respectively adjacent layers 9 b and be provided 10 b, so that the following applies: Ms ₂ '= Ms ₂ and Ms ₃ ′ = Ms ₃. However, you can also choose different materials.

It is particularly advantageous if at least some of the individual magnetic layers of the magnetic head 2 shown in the figure are provided with materials which, in addition to the predetermined saturation magnetizations, also have different permeabilities. In the following, the reversible permeability µ of the materials is taken as a basis. Thus one can, in particular for the gap 13 defining the magnetic layer 9 b of the front running magnetic leg 9 a material provide its permeability μ ₂ is greater than the Permeabi formality μ ₁ their at least 13 be adjacent in the region of the gap, facing the substrate 3 magnetic layer 9 a . For the magnetic layers 10 a and 10 b of the trailing magnetic leg 10 , materials with a permeability µ ₃ are selected, which is also advantageously smaller than the permeability µ ₂ and can be for example equal to µ ₁. If necessary, one can also provide materials with different permeabilities µ ₂ and µ ₃ for the additional magnetic layers 9 c and 10 c . In this example, these can Perme abilitäten equal to the permeability μ ₂ or μ ₁ of the materials of the adjacent legs in the respective magnetic layers to be 9 b and 10 b, so that then applies μ ₃ = μ ₁ and μ ₂ = μ ₁ . With such a choice of the permeabilities of the effect is supported, that for the reading function, the gap 13 adjacent to the magnetic layer 9 b of the preceding magnetic limb 9 in thus smaller gap width w is effective.

If necessary, instead of several adjacent magnetic layers made of the same material, it is also possible to provide only a single layer with a correspondingly greater layer thickness. For example, layers 10 a and 10 b could be combined into a single layer of thickness ( d _a '+ d _b ') if they cannot be created from materials with different saturation magnetization and / or reversible permeability.

Claims (15)

1. Thin-film magnetic head with a layered structure on a non-magnetic substrate for a recording medium, which is provided with a magnetizable storage layer, in which along a track information by longitudinal (horizontal) or vertical (vertical) magnetization of the storage layer are to be registered, which magnetic head has a magnetic flux guiding, ring head-like magnetic guide body with two magnetic legs,

• - Which consist of material of predetermined saturation magnetization,
• - The magnetic poles facing the recording medium are arranged one behind the other in the (relative) direction of movement of the head, a gap having a predetermined width being formed, and
• - The outside of the pole area delimit an intermediate space through which the windings of a write and / or read coil winding extend,

characterized in that seen in the direction of movement (v) leading magnetic leg ( 9 ) has at least two magnetic layers ( 9 a , 9 b , 9 c) made of materials of different saturation magnetization (Ms ₁, Ms ₂. Ms ₂ ′ ) , the magnetic layer ( 9 b) from the one material with the comparatively smaller saturation magnetization (Ms ₂) limits the gap ( 13 ) and in the write function due to a write current (I) flowing in the coil winding ( 18 ) into the area of the associated magnetic pole ( P ₁ ) in the magnetic saturation is driven

• - The trailing magnetic leg ( 10 ) contains at least one magnetic layer ( 10 a , 10 b , 10 c ), the material of which has a saturation magnetization ( Ms ₃, Ms ₃ ') that is greater than the comparatively smaller saturation magnetization ( Ms ₂) the gap ( 13 ) delimiting magnetic layer ( 9 b) of the leading magnetic leg ( 9 ), and
• - The area occupied by the magnetic pole ( P ₂ ) of the trailing magnetic leg ( 10 ) ( F ₂ ) is at least as large as the area ( F ₁ ) of the magnetic pole ( P ₁ ) of the leading magnetic leg ( 9 ).

2. Magnetic head according to claim 1, characterized in that the area occupied by the magnetic pole ( P ₂ ) of the trailing magnetic leg ( 10 ) ( F ₂ ) is at least 1.5 times, preferably at least twice, so large like the surface ( F ₁ ) of the magnetic pole ( P ₁ ) of the leading magnetic leg ( 9 ). 3. Magnetic head according to claim 1 or 2, characterized in that the trailing magnetic leg ( 10 ) outside the area of its one magnetic pole ( P ₂ ) forming end piece ( 12 ) at least one further magnetic layer ( 10 c) from a mate rial, whose saturation magnetization (Ms ₃ ') is greater than the saturation magnetization (Ms ₂) of the material of the gap ( 13 ) delimiting magnetic layer ( 9 b) of the leading magnetic leg ( 9 ). 4. Magnetic head according to claim 3, characterized in that the magnetic layers ( 10 a , 10 b , 10 c ) of the trailing magnetic leg ( 10 ) consist of the same material. 5. Magnetic head according to one of claims 1 to 4, characterized in that the leading magnetic leg ( 9 ) outside the region of its one magnetic pole ( P ₁ ) forming end piece ( 11 ) has at least one further magnetic layer ( 9 c) made of one material , whose saturation magnetization (Ms ₂ ′) is smaller than the saturation magnetization (Ms ₁) of the material of its magnetic layer ( 9 a) which is further away from the gap ( 13 ) . 6. Magnetic head according to claim 5, characterized in that the further magnetic layer ( 9 c) of the leading magnetic leg ( 9 ) and the adjacent, the gap ( 13 ) delimiting magnetic layer ( 9 b) consist of the same material. 7. Magnetic head according to claims 3 or 4 and 5 or 6, characterized in that the thickness ( d _c ) of the further magnetic layer ( 9 c) of the before running magnetic leg ( 9 ) is less than the thickness (d _c ') of the other Magnetic layer ( 10 c) of the magnetic leg ( 10 ) running. 8. A magnetic head according to any one of claims 1 to 7, as by in that the magnetic layer located further away from the gap (13) (9 a) of the preceding magnetic limb (9) and the at least one magnetic layer (10 a, 10 b, 10 c ) of the running magnetic leg ( 10 ) made of the same material with the comparatively larger saturation magnetization (Ms ₁, Ms ₃, Ms ₃ '). 9. Magnetic head according to one of claims 1 to 8, characterized in that the gap ( 13 ) delimiting magnetic layer ( 9 b) of the vorlau fenden magnetic leg ( 9 ) consists of a material whose saturation magnetization (Ms ₂) at least by a factor 1.2 is smaller than the saturation magnetization (Ms ₁) of the material of the adjacent, from the gap ( 13 ) further away magnetic layer ( 9 a) of this leg ( 9 ). 10. Magnetic head according to one of claims 1 to 9, characterized in that the comparatively smaller saturation magnetization (Ms ₂, Ms ₂ ') is below 10 kA / cm. 11. Magnetic head according to one of claims 1 to 10, characterized in that the comparatively larger saturation magnetization (Ms ₁, Ms ₃, Ms ₃ ') has a value above 10 kA / cm, preferably above 12 kA / cm. 12. Magnetic head according to one of claims 1 to 11, characterized in that at least some of the magnetic layers ( 9 a to 9 c, 10 a to 10 c ) of the two magnetic legs ( 9 , 10 ) made of materials of different reversible permeability ( µ ₁ to µ ₃, µ ₂ ′, µ ₃ ′) exist. 13. Magnetic head according to claim 12, characterized in that the material with the comparatively smaller saturation magnetization ( Ms ₂, Ms ₂ ') of the at least one magnetic layer ( 9 b , 9 c) of the leading magnetic leg ( 9 ) has a permeability ( µ ₂, µ ₂ ′), which is greater than the permeability ( µ ₁, µ ₃, µ ₃ ′) of the materials of the magnetic layers ( 9 a , 10 a to 10 c) with the greater saturation magnetization ( Ms ₁, Ms ₃ , Ms ₃ ′).