JPH0944816A - Magnetic head - Google Patents

Abstract

PROBLEM TO BE SOLVED: To set the gap length different from each other at the time of recording and reproducing in an in-gap type magnetic head. SOLUTION: A reproducing element 3 which exhibits a magneto-resistive effect is disposed between cores 12 and 13 for recording. The core 13 has a first magnetic layer 13a and a second magnetic layer 13b. The gap length at the time of recording is L1 and the gap length at the time of reproducing is L2 when the saturation magnetization of the magnetic layer 13b is set smaller than the saturation magnetization of the magnetic layer 13a. Recording magnetic fields of a spatial spread are thereby generated and the resolution at the time of reproducing is enhanced. The gap length at the time of reproducing may be set at L1 and the gap length at the time recording at L2 if the magnetic layer 13b is so formed as to have the coercive force larger than the magnitude of the magnetic field from a recording medium. As a result, the high-density recording is made possible and the stable reproduced output is obtd.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetic head capable of performing magnetic recording on a magnetic medium such as a disk and obtaining a magnetic reproduction output from the magnetic medium, and particularly to a magnetoresistive effect between a pair of recording cores. The present invention relates to a magnetic head provided with a reproducing element that obtains a reproduced output.

[0002]

2. Description of the Related Art There is known a thin film magnetic head for performing magnetic recording on a magnetic medium such as a hard disk and reproducing a magnetic signal recorded on the magnetic medium. In a conventional general thin film magnetic head, a reproducing element that exhibits a magnetoresistive effect is provided between shield layers, and an inductive recording head having a recording core and a thin film coil is provided outside the shield layer. It has been set.

However, in the above-mentioned thin film magnetic head,
Since the reproducing gap for reproducing the magnetic signal by the reproducing element and the recording gap for recording the magnetic signal by the recording core are located apart from each other, recording and reproducing of the magnetic signal in a limited area of the recording medium. In this case, since it is necessary to position the reproduction track with respect to the recording track, and the recording head is superposed on the reproduction head, the overall layer structure becomes complicated, and the manufacturing process becomes complicated. There is.

Therefore, a so-called in-gap type thin film magnetic head shown in FIG. 4 has been proposed. This thin-film magnetic head has inductive type recording cores 1 and 2. The right end of the recording core 2 in the figure is joined to the recording core 1, and a thin film coil is formed around this joint. At the portion A facing the magnetic medium, the reproducing element 3 is provided in the gap where the recording cores 1 and 2 face each other. The reproducing element 3 is capable of detecting a magnetic field from a magnetic medium by a magnetoresistive effect, and is usually a soft magnetic layer (SAL layer) 3a, a nonmagnetic layer (SHUNT layer) 3b and a ferromagnetic layer (MR layer) 3c. It has a three-layer structure.
Further, the reproducing element 3 is provided with bias means for applying a longitudinal bias magnetic field in the z direction to the ferromagnetic layer 3c.

In the hard disk device, the thin film magnetic head is formed on the trailing side end surface of the flying slider, and the facing portion A floats and faces the surface of the magnetic medium (disk). The moving direction of the magnetic medium with respect to the magnetic head is the x direction, and the detection direction of the magnetic field generated from the magnetic medium is the y direction.

At the time of recording, a magnetic field generated from the thin film coil is applied to the recording cores 1 and 2, and a magnetic signal is recorded on the recording medium by the magnetic gap between the cores 1 and 2 at the facing portion A. The recording gap length at this time is L. During reproduction, the electric resistance of the reproducing element 3 changes due to the magnetic field (leakage magnetic field) generated in the y direction from the recording medium, and the reproducing element 3
The magnetic signal is detected by the voltage drop of the steady current applied to the. During reproduction, the recording cores 1 and 2 function as shield layers against the magnetic field from the recording medium. Therefore, the range of the magnetic field that can be detected by the reproducing element 3, that is, the reproducing gap length is L, as described above.

[0007]

However, in the conventional in-gap type magnetic head shown in FIG. 4, the gap length at the time of recording and the gap length at the time of reproduction (magnetic detection range) are both the same L. is there. Therefore, the following problems occur. (1) In a magnetic recording / reproducing device using a magnetic medium having a large magnetic layer thickness, or in a fixed disk device in which the flying distance of the facing portion A of the magnetic head from the surface of the magnetic medium is relatively high, the core 1 It is preferable to generate a magnetic field of a certain magnitude from the gap with 2 so as to have a spatial spread. In this case, the gap length L at the time of recording is preferably large. However, if the gap length L is increased, the gap length during reproduction also increases, and the resolution during reproduction of the magnetic signal decreases. On the contrary, if the gap length L is reduced to increase the resolution during reproduction, the spatial spread of the magnetic field applied from the gap during recording is narrowed,
The recording characteristics will deteriorate.

(2) Further, the magnetic recording on the magnetic medium in the future is required to have a higher density. In this case, a material having a higher coercive force than that of the present is used as the material of the magnetic layer of the magnetic medium. Become. In order to perform high-density recording of a magnetic signal on a magnetic medium using a magnetic material having a high coercive force, it is necessary to make the levitation distance between the facing portion A of the magnetic head and the surface of the magnetic medium even lower than the current one. In addition, it is necessary to form the recording cores 1 and 2 with a magnetic material having a large saturation magnetization or to narrow the recording gap length L. However, if the gap length L is extremely shortened, the reproducing element 3 and the recording cores 1 and 2 functioning as shield layers are formed.
The interval between and becomes shorter. If this interval becomes extremely short, the magnetic stability of the reproducing element 3 will be impaired and Barkhausen noise will increase. Further, it becomes impossible to obtain a sufficient magnetic reproduction output by the reproducing element 3. Therefore, in the conventional magnetic head shown in FIG. 4, there is a limit in shortening the gap length L, and it becomes difficult to cope with high density recording using a magnetic medium having a high coercive force.

(3) As described above, in the in-gap type magnetic head, when the recording gap length and the reproducing gap length are the same dimension L, the facing portion A of the magnetic head as in the current fixed disk device or the like. If the flying distance between the magnetic recording medium and the surface of the magnetic medium is relatively high, either the recording characteristics or the resolution during reproduction must be sacrificed, and the high coercive force to support future high density recording. In a device using the magnetic medium of No. 2, if a stable reproduction output is to be obtained from the reproduction element 3, there is a limit to narrowing the recording gap length.

The present invention solves the above-mentioned conventional problems and is effective in an in-gap type by increasing the gap length during recording and reducing the gap length (magnetic detection range) during reproduction. It is an object of the present invention to provide a magnetic head that can obtain recording characteristics and can increase the resolution during reproduction.

The present invention, in the in-gap type, makes the gap length during recording small and the gap length during reproduction (magnetic detection range) large so as to enable recording with a narrow gap and to obtain a high coercive force. It is an object of the present invention to provide a magnetic head which is adapted to high density recording on a magnetic medium and which does not extremely reduce the gap length during reproduction and does not impair the magnetic stability of a reproducing element.

[0012]

A magnetic head according to a first aspect of the present invention provides a pair of recording cores facing each other with a gap in a facing portion to a magnetic medium, and a recording magnetic field is applied to the recording cores. A magnetic field generating means and a reproducing element located between the recording cores at the facing portion to obtain a reproduction output by a magnetoresistive effect are provided, and at least one of the pair of recording cores has a first magnetic field. Has a laminated structure of a layer and a second magnetic layer facing the reproducing element, wherein the second magnetic layer is
It is characterized by being formed of a material having a saturation magnetization smaller than that of the first magnetic layer.

The magnetic head according to the second aspect of the present invention comprises a pair of recording cores facing each other with a gap in the portion facing the magnetic medium, magnetic field generating means for applying a recording magnetic field to the recording cores, and A reproducing element that is located between the recording cores at the facing portion to obtain a reproduction output by a magnetoresistive effect is provided, and at least one of the pair of recording cores has a first portion.
Magnetic layer and a second magnetic layer facing the reproducing element, the second magnetic layer is made of a material having a coercive force larger than the magnitude of the magnetic field generated from the magnetic medium. It is characterized by that. That is, the second magnetic material is formed of a material having a high coercive force and a low magnetic permeability, and this material has a relative magnetic permeability (vacuum depth direction; y direction) in the magnetic field detection direction from the magnetic medium. It is preferable that the ratio (with respect to the magnetic permeability) is close to 1.

The coercive force of the material forming the second magnetic layer is preferably at least twice the magnitude of the magnetic field generated from the magnetic medium.

Further, the saturation magnetization of the second magnetic layer is
It is possible to make it larger than the saturation magnetization of the magnetic layer.

[0016]

In the magnetic head of the present invention, at least one of the pair of recording cores forming the inductive head to which the magnetic field for recording is applied from the magnetic field generating means such as a thin film coil, that is, both or one of them has a laminated structure. First
Magnetic layer and a second magnetic layer on the side facing the reproducing element. A reproducing element that obtains a reproduced output by the magnetoresistive effect is provided between both recording cores.

In the first aspect of the present invention, the second magnetic layer is made of a material having a smaller saturation magnetization than that of the first magnetic layer. At the time of recording, the recording magnetic field is applied to the recording core from the magnetic field generating means. At this time, since the saturation magnetization of the second magnetic layer is small, the recording magnetic field is saturated, and the portion of the second magnetic layer is used for recording. It will not function as a core. Therefore, the gap length during recording is determined by the distance between the first magnetic layer and the recording core on the other side. Therefore, the gap length during recording becomes large. Further, by forming the second magnetic layer from a material having a magnetic permeability to some extent, preferably a material having a magnetic permeability equal to or higher than that of the first magnetic layer, the second magnetic layer can be reproduced. Functions as a shield layer facing the reproducing element. Therefore, during playback, the second
Both the magnetic layer and the recording core on the other side function as a shield layer, and the gap length (magnetic detection range) during reproduction is determined by the distance between the two layers.

Therefore, the magnetic head of the first aspect of the present invention constitutes a magnetic head having a wide recording gap length and a narrow reproducing gap length. With this magnetic head, a large magnetic field can be generated from the gap between the recording cores with a wide space at the time of recording, and the fixed disk device in which the flying distance between the magnetic head and the magnetic medium is relatively large, and the magnetic layer has a large thickness Good recording characteristics can be obtained in an apparatus using a magnetic medium. Further, since the narrow gap length is obtained during reproduction, the reproduction resolution of the magnetic signal in the reproduction element can be increased.

In the second aspect of the present invention, the second magnetic layer is
It is formed of a material having a coercive force larger than that of the magnetic field generated from the magnetic medium, preferably a material having a coercive force twice or more the magnitude of the magnetic field applied from the magnetic medium to the second magnetic layer. Further, preferably, the second magnetic layer is formed of a material having a relative magnetic permeability close to 1 in the detection direction (y direction) of the magnetic field from the recording medium. During reproduction, the magnetization of the second magnetic layer does not change due to the magnetic field emitted from the magnetic medium, and the second magnetic layer does not function as a shield layer for the reproducing element. Therefore, the first magnetic layer and the recording core on the opposite side function as a shield layer, and the distance between the two layers becomes the gap length during reproduction.

At the time of recording, the first magnetic field generating means is used for the first recording.
A recording magnetic field is applied to the first magnetic layer and the second magnetic layer. Therefore, it is necessary that the second magnetic layer has a coercive force sufficiently smaller than the magnitude of the recording magnetic field generated from the magnetic field generating member. Since the second magnetic layer can function as a recording core during recording, the gap length during recording is determined by the distance between the second magnetic layer and the recording core on the other side.

The magnetic head according to the second aspect of the present invention has a narrow recording gap length and a wide reproducing gap length. Therefore,
When the density of the magnetic medium is increased and the magnetic layer of the magnetic medium has a high coercive force, the narrow recording gap length facilitates high-density recording of a signal on the magnetic medium having a high coercive force. In addition, since the wide reproduction gap length is obtained during reproduction, the reproduction gap length can be increased even if the gap length during recording is extremely narrow, so that the magnetic stability of the reproduction element utilizing the magnetoresistive effect is secured. It is possible to obtain a sufficiently large reproduction output. If the gap length during reproduction is widened, the resolution will decrease when reproducing high density recording signals. However, in the reproducing element utilizing the magnetoresistive effect, since the reproducing output can be increased to some extent, a certain resolution can be secured without extremely reducing the gap length during reproducing. In the future, P will be used as a signal processing method for high-density recording.
When the RML method is adopted, the resolution does not become a problem as much as the conventional one. That is, in a high-density recording method using a magnetic medium with high coercive force, when the gap length during recording is reduced, the gap length during reproduction should be slightly wider than this to ensure the magnetic stability of the reproducing element. Is effective in exhibiting the characteristics of the device.

Further, in order to perform high density recording on a magnetic medium having a high coercive force, it is necessary to shorten the flying distance between the magnetic head and the magnetic medium and reduce the gap length during recording as described above. However, in order to enable higher density recording, the saturation magnetization of the second magnetic layer is made larger than the saturation magnetization of the first magnetic layer, and the recording magnetic field applied from the recording core to the magnetic medium is further increased. Preferably.

[0023]

Embodiments of the present invention will be described below with reference to the drawings. 1 is an enlarged sectional view showing a portion of a magnetic head of a first embodiment of the invention facing a magnetic medium, FIG. 2 is a sectional view showing the whole structure of the magnetic head, and FIG. 3 is a second embodiment of the invention. FIG. 3 is an enlarged cross-sectional view showing a portion of the magnetic head of FIG. As shown in FIG. 2, the magnetic head H of this embodiment is of the in-gap type. The magnetic head H is used in, for example, a hard disk device. Reference numeral 11 is a slider, and an ABS surface 11a of the slider 11 faces a disk which is a magnetic medium. The magnetic head H of the present invention is provided on the trailing end surface 11b of the slider 11.

A first recording core 12 is formed in a thin film on the trailing side end surface 11b, and the first recording core 1 is formed.
A second recording core 13 is provided on the second recording medium 2. Second
The connecting portion 13d of the recording core 13 of the first recording core 1 is
Connected to 2. Centering around this connection 13d,
A thin film coil 14 as a magnetic field generating means formed in a planar spiral shape is provided. At the facing portion Ha of the magnetic head H facing the magnetic medium, a reproducing element 3 is provided between the first recording core 12 and the second recording core 13 to obtain a reproduction output by the magnetoresistive effect. In addition, the first recording core 12, the second recording core 13, the thin film coil 1
4 and each layer of the reproducing element 3 are insulated by a magnetic insulating layer 15 such as Al ₂ O ₃ .

The reproducing element 3 is capable of detecting the magnetic field from the magnetic medium by the magnetoresistive effect, and has a soft magnetic layer (SA).
It has a three-layer structure of an L layer) 3a, a non-magnetic layer (SHUNT layer) 3b and a ferromagnetic layer (MR layer) 3c. Further, the reproducing element 3 is provided with bias means for applying a longitudinal bias magnetic field in the z direction to the ferromagnetic layer 3c, and a lead wiring layer for applying a steady current in the z direction to the reproducing element 3.
The ABS surface 11a of the slider 11 and the facing portion Ha of the magnetic head H float and face the surface of the magnetic medium (disk). The moving direction of the magnetic medium with respect to the magnetic head H is the x direction, and the detection direction of the magnetic field generated from the magnetic medium is the y direction.

As shown in FIG. 1, the second recording core 13
Has a laminated structure of a first magnetic layer 13a and a second magnetic layer 13b. The second magnetic layer 13b is located inside the second recording core 13 and faces the reproducing element 3 and the first recording core 12. In the example corresponding to the first aspect of the present invention, the saturation magnetization (Bs) of the second magnetic layer 13b is smaller than the saturation magnetization of the first magnetic layer 13a.
As a specific material for forming each magnetic layer, a combination of the first magnetic layer 13a is a Ni-Fe (nickel-iron) alloy and a second magnetic layer 13b is a Ni-Fe-X alloy, or a first material. The magnetic layer 13a may be a combination of a Co-Ni-Fe (cobalt-nickel-iron) alloy and the second magnetic layer 13b may be a combination of a Co-X alloy. In the above, X is Al
(Aluminum), Nb (niobium), Cr (chrome),
It is one of metals such as Ti (titanium), Rh (rhodium), and Zr (zirconium). The first recording core 12 is made of the same magnetic material as that of the first magnetic layer 13a, and may be, for example, a Ni—Fe alloy or Co—Ni—.
Fe alloy and the like.

In the embodiment of the first invention, the second magnetic layer 1
Since the saturation magnetization (Bs) of 3b is small, a recording current is applied to the thin film coil 14 during recording, and the recording cores 12 and 13 are
When a recording magnetic field is applied to the second magnetic layer 13b, the magnetization of the second magnetic layer 13b is completely saturated, and the second magnetic layer 13b does not function as a recording core. Therefore, the gap length during recording is the first
The distance L1 between the magnetic layer 13a and the recording core 12 is determined. During reproduction, the second magnetic layer 13b functions as a shield layer for the reproducing element 3. Therefore, the gap length (magnetic detection range) during reproduction is determined by the distance L2 between the second magnetic layer 13b and the recording core 12.

From the above, in the first embodiment of the present invention, a magnetic head having a wide recording gap length L1 and a narrow reproducing gap length L2 is constructed. This magnetic head can generate a recording magnetic field with a certain degree of spatial expansion due to the gap length L1 at the time of recording, and a magnetic signal is recorded on the magnetic medium by this magnetic field. Therefore, effective magnetic recording can be performed in a fixed disk device having a large flying distance of the facing portion Ha from the magnetic medium or a magnetic recording / reproducing device using a magnetic medium having a large magnetic layer thickness. Also, since the gap length L2 during reproduction is small,
The resolution during playback can be increased.

In the second aspect of the present invention, the coercive force (Hc) of the second magnetic layer 13b is larger than the magnitude of the magnetic field generated from the magnetic medium. The coercive force of the second magnetic layer 13b is twice or more of the magnitude of the magnetic field applied from the medium to the second magnetic layer 13b). For example, when the magnetic field applied from the magnetic medium to the second magnetic layer 13b is 40 to 50 (Oe: Oersted), the coercive force (Hc) of the second magnetic layer 13b is 100 (Oe) or more. The coercive force of the first magnetic layer 13a needs to be smaller than the coercive force of the second magnetic layer 13b, that is, the coercive force is smaller than the magnitude of the magnetic field from the magnetic medium. Further, the second magnetic layer 13b preferably has a small magnetic permeability (μ) in the gap depth direction (y direction), and a relative magnetic permeability (ratio to magnetic permeability in vacuum) is preferably close to 1. .

In the magnetic head of the second aspect of the present invention, during reproduction by the reproducing element 3, the magnetization of the second magnetic layer 13b does not change with respect to the magnetic field generated by the magnetic medium, and the second magnetic layer 13b reproduces. It does not function as a shield layer for the element 3. The first magnetic layer 13a and the recording core 12 are the second
Since the coercive force is smaller than that of the magnetic layer 13b and the coercive force is smaller than the magnitude of the magnetic field from the magnetic medium, the first magnetic layer 13a and the recording core 12 function as a shield layer. Therefore, the gap length during reproduction is L1. Also,
At the time of recording, due to the magnetic field generated from the thin film coil 14,
The magnetization of the second magnetic layer 13b is changed similarly to the first magnetic layer 13a and the recording core 12. Therefore, the recording gap length is L2.

From the above, in the second invention, a magnetic head having a wide reproduction gap length L1 and a narrow recording gap length L2 is constructed. Further, in order to generate a high recording magnetic field at the narrow gap length L2 during recording, the saturation magnetization (Bs) of the second magnetic layer 13b is equal to or more than the saturation magnetization of the first magnetic material 13a. Preferably there is.

A combination of materials of the respective layers for increasing the coercive force and the magnetic permeability of the second magnetic layer 13b and making the saturation magnetization larger than that of the first magnetic layer 13a will be exemplified. When the first magnetic layer 13a is a Ni—Fe alloy, the second magnetic layer 13b is a Co—Ni—Fe alloy, or when the first magnetic layer 13a is a Co ₇₀ —X alloy, the second magnetic layer 13a is a second magnetic layer. the layers 13b may be mentioned a combination and Co ₈₅ -X alloy. In the above, X is Al (aluminum), Nb (niobium), Cr (chrome), Ti
(Titanium), Rh (Rhodium), V (Vanadium), Z
It is one of metals such as r (zirconium), Mo (molybdenum), Hf (hafnium), Ta (tantalum), and W (tungsten). The recording core 12 is the first
The magnetic layer 13a is made of the same material.

Since the magnetic head of the second aspect of the present invention has a narrow recording gap length L2 and the saturation magnetization of the second magnetic layer 13b is increased, a large recording magnetic field can be applied to the magnetic medium with a narrow gap. It is possible to give high density recording to a magnetic medium having a high coercive force. Further, during reproduction, reproduction can be performed with a wider gap length L1 than during recording, so the reproduction gap length does not become extremely narrow, the magnetoresistive effect of the reproducing element can be stabilized, and a high reproduction output can be obtained. That is, even if the gap length L2 at the time of recording is made sufficiently small, it has a wider gap length than that at the time of reproduction, and it is possible to prevent the reproduction capability from being deteriorated due to the narrow gap length. Therefore, the gap length during recording can be made as small as possible, and the magnetic head can be used for high density recording.

Further, as shown in FIG. 3, the recording core 13
May have a laminated structure of the first magnetic layer 13a and the second magnetic layer 13b, and further may have a structure in which a third magnetic layer 13c is laminated outside the first magnetic layer 13a. For example, in the first embodiment of the present invention, the first magnetic layer 13a is made of a material having a larger saturation magnetization than the third magnetic layer 13c, and the second magnetic layer 13b is made of a material having a small saturation magnetization. . As a result, a strong recording magnetic field can be generated with a wide gap length during recording, and a narrow gap length is achieved during reproduction. In the second aspect of the present invention, the first magnetic layer 13a and the second magnetic layer 1
3b is formed of a material having a saturation magnetization larger than that of the third magnetic layer 13c so that a large magnetic field can be generated with a narrow gap length at the time of recording, and the second magnetic layer 13b has a magnetic field generated from a magnetic medium. As the coercive force is greater than the size, the gap length can be increased during reproduction.

The first recording core 12 may have a laminated structure similar to that of the recording core 13 shown in FIG. 1 or 3, or both the cores 12 and 13 may have a laminated structure.

[0036]

As described above, according to the first aspect of the present invention, in the in-gap type magnetic head, the gap length during recording can be increased and the gap length during reproduction can be reduced. Therefore, it is possible to effectively perform recording on the magnetic medium by the recording magnetic field having a spatial expansion at the time of recording, and it is possible to improve the resolution by the narrow gap at the time of reproducing.

In the second aspect of the present invention, the gap length during recording can be reduced and the gap length during reproduction can be increased. Therefore, high density recording on a magnetic medium with high coercive force becomes possible,
Further, it is possible to prevent the adverse effect of the narrow gap during reproduction, that is, the magnetic destabilization of the reproducing element.

[Brief description of drawings]

FIG. 1 is an enlarged sectional view showing a portion of a magnetic head of the present invention facing a magnetic medium,

FIG. 2 is a sectional view showing the overall structure of a magnetic head of the present invention,

FIG. 3 is an enlarged cross-sectional view showing a portion of a magnetic head according to another embodiment of the present invention which faces a magnetic medium,

FIG. 4 is an enlarged cross-sectional view showing a portion of a conventional magnetic head facing a magnetic medium,

[Explanation of symbols]

 3 reproducing element 12 and 13 recording core 13a first magnetic layer 13b second magnetic layer 14 thin film coil (magnetic field generating means)

Claims (4)

[Claims] 1. A pair of recording cores facing each other with a gap at a portion facing a magnetic medium, a magnetic field generating means for applying a recording magnetic field to the recording cores, and the recording core at the facing portion. A reproducing element that is located between them and obtains a reproduction output by a magnetoresistive effect is provided, and at least one of the pair of recording cores has a first magnetic layer and a second magnetic layer facing the reproducing element. And a second magnetic layer formed of a material having a smaller saturation magnetization than that of the first magnetic layer. 2. A pair of recording cores facing each other with a gap in a portion facing the magnetic medium, a magnetic field generating means for applying a recording magnetic field to the recording core, and the recording core in the facing portion. A reproducing element that is located between them and obtains a reproduction output by a magnetoresistive effect is provided, and at least one of the pair of recording cores has a first magnetic layer and a second magnetic layer facing the reproducing element. And a second magnetic layer formed of a material having a coercive force larger than the magnitude of the magnetic field generated from the magnetic medium. 3. The magnetic head according to claim 2, wherein the coercive force of the material forming the second magnetic layer is at least twice the magnitude of the magnetic field generated from the magnetic medium. 4. The magnetic head according to claim 2, wherein the saturation magnetization of the second magnetic layer is larger than the saturation magnetization of the first magnetic layer.