Method of manufacturing a spin-valve giant magnetoresistive head
Multiple thin films of spin-valve GMR sensor are formed in a trapezoidal cross-sectional shape by laminating an antiferromagnetic layer, a pinned magnetic layer, a nonmagnetic conductive layer, a free magnetic layer and a nonmagnetic protective layer on a lower insulated gap layer. The amount of etching of the lower insulated gap layer produced in the process of patterning the spin-valve giant magnetoresistive layers into the multiple thin films of spin-valve GMR sensor is 10 nm or less. Further, the angle θ which the tangent line of each side face of the multiple thin films to the middle line of the free magnetic layer in its thickness direction forms with respect to the middle line of the free magnetic layer becomes 45 degrees or more. This structure makes it possible to provide such a spin-valve giant magnetoresistive head that it meets the requirements for securing constant breakdown voltage and preventing instability of MR output voltage waveform.
This is a divisional of U.S. application Ser. No. 10/778,079, filed Feb. 17, 2004, which is a divisional of U.S. application Ser. No. 09/931,255, filed Aug. 17, 2001 (now U.S. Pat. No. 6,717,778). This application relates to and claims priority from Japanese Patent Application No. 2000-365771, filed on Nov. 28, 2000. The entirety of the contents and subject matter of all of the above is incorporated herein by reference.
BACKGROUND OF THE INVENTION1. Field of the Invention
The present invention relates to a spin-valve giant magnetoresistive head for reproducing magnetic information written in a minute single domain on a magnetic recording medium in a magnetic recording apparatus for use in a computer, an information processing apparatus and the like. In particular, the present invention relates to a spin-valve giant magnetoresistive head and its manufacturing method suitably used to prevent instability of magnetoresistive (MR) output voltage waveform caused by Barkhausen noise and obtain adequate MR output voltage, especially in a narrow-track head necessary to achieve high-density magnetic recording.
2. Description of the Related Art
A thin-film magnetic head for writing and reading magnetic information is a key device to a magnetic recording apparatus. The thin-film magnetic head consists of a inductive write head for writing magnetic information and a read head for reading out the magnetic information written in a recording medium.
The read head for reading out the magnetic information from the recording medium includes a magnetoresistive element showing a resistance change to a very weak magnetic field applied from the outside, or a giant magnetoresistive element showing a resistance change larger than that of the magnetoresistive element. The reproducing head also includes a conductive film for supplying sensing current for use in sensing the resistance change.
The spin-valve giant magnetoresistive head that shows a large MR ratio to an applied magnetic field to produce a resistance change to a very weak magnetic field includes multiple thin films of giant magnetoresistive (GMR) sensor. The multiple thin films of GMR sensor are composed of at least an antiferromagnetic layer, a pinned magnetic layer, a free magnetic layer, a nonmagnetic conductive spacer that achieves magnetic insulation between the pinned magnetic layer and the free magnetic layer, and a nonmagnetic protective layer. The spin-valve giant magnetoresistive head also includes magnetic-domain control layers that maintain the magnetic orientation of the free magnetic layer in such a state that it intersects at right angles to that of the pinned magnetic layer. Further, the spin-valve giant magnetoresistive includes a conductive layer that supplies sensing current to the multiple thin films of GMR sensor to sense the resistance change.
In the spin-valve giant magnetoresistive head, a magnetic field necessary for magnetic-domain control is applied to the free magnetic layer to make a single domain of the free magnetic. This technique is important for preventing instability of MR output voltage waveform caused by Barkhausen noise.
Magnetic-domain control layers 9 are formed on the side inclined parts of the multiple thin films of GMR sensor D2 and the lower insulated gap layer 42. The magnetic-domain control layers 9 make the magnetic orientation of the free magnetic layer 4 aligned in such a direction that it intersects at right angles to the magnetic orientation of the pinned magnetic layer 2. Base material layers 8 for the respective magnetic-domain control layers 9 are formed under the magnetic-domain control layers 9. Conductive layers 11 for supplying sensing current to the multiple thin films of GMR sensor to sense a magnetic resistance change are formed above the magnetic-domain control layers 9 through base material layers 10 for the respective conductive layers 11. An upper insulated gap layer 47 and an upper magnetic shield layer 48 are formed over the multiple thin films of GMR sensor D2 and the conductive layers 11.
In such a spin-valve giant magnetoresistive head, a magnetic field enough for magnetic-domain control is applied to the free magnetic layer 4, which makes it possible to prevent generation of Barkhausen noise, and hence instability of MR output voltage waveform. Thus a stable head can be provided.
One approach to reducing Barkhausen noise to prevent instability of MR output voltage waveform is described, for example, in JP-A-2000-215424. This publication presents such a structure that a flat part of a hard-bias layer having larger thickness than that of a free magnetic layer is positioned in the thickness direction of the free magnetic layer at the same level as the free magnetic layer. The free magnetic layer corresponds to the above-mentioned free magnetic layer 4. The generation of instable MR output, however, cannot be prevented by this approach alone.
SUMMARY OF THE INVENTIONIt is an object of the present invention to provide a spin-valve giant magnetoresistive head and its manufacturing method capable of restraining instability of MR output voltage waveform.
To prevent generation of an instable MR output voltage waveform in a spin-valve giant magnetoresistive head, we directed our attention to the inclined angles of end parts of the free magnetic layer of end parts of multiple thin films of GMR sensor. We created spin-valve giant magnetoresistive heads with varied and inclined angles of end parts of the free magnetic layer of GMR sensor and measured the probability of occurrence of an instable MR output voltage waveform. Experimentally, it becomes apparent from the results of the measurement that variations in inclined angles of the end parts of the free magnetic layer of GMR sensor vary the probability of instability of MR output waveform caused by Barkhausen noise. It was found that the end parts of the multiple thin films of GMR sensor should be so made that the angle which the tangent line of each end inclined part to the middle line of the free magnetic layer in its thickness direction forms with respect to the middle line of the free magnetic layer is 45 degrees or more.
It is true that the tangent line of each inclined end part of the multiple thin films of GMR sensor to the middle line of the free magnetic layer in its thickness direction should form an angle of 45 degrees or more with respect to the middle line of the free magnetic layer, regardless of whether the antiferromagnetic layer in the giant magnetoresistive thin films is of one-layer or two-layer structure.
To make the inclined angles of the end parts of the free magnetic layer of the multiple thin films of GMR sensor form an angle of 45 degrees or more, after giant magnetoresistive thin films are formed, over etching is conducted onto the giant magnetoresistive thin films by ion milling or the like using a mask pattern such as a resist mask pattern. Thus the inclined end parts can form an angle of 45 degrees or more. The term “over etching” denotes an etching process that takes a longer time than that required for etching of the above-mentioned giant magnetoresistive thin films. In this case, however, the lower magnetic gap film formed under the giant magnetoresistive thin films is also etched in this over etching process, the thickness of portions of the lower magnetic gap film directly under the openings of the photoresist mask pattern is reduced. The lower magnetic gap film is a nonmagnetic insulated film made of Al2O3 or SiO2 or both. As this film becomes thin, breakdown voltage between the film such as the magnetic-domain control layer or the conductive layer and the lower shield layer is made small, which runs the danger of reducing the performance of the magnetic head.
Experiments on this point revealed that the amount of reduction in the thickness of the portion between the magnetic-domain control layer and the lower shield layer relative to the thickness of the lower insulated gap film directly under the giant magnetoresistive thin films should be 10 nm maximum. In other words, the difference between the thickness of the portions of the lower insulated gap layer directly under the giant magnetoresistive thin films and the thickness of the lower insulated gap layer sandwiched between the magnetic-domain control layer and the lower shield layer should be 10 nm or less. This means that the amount of over etching in the process of forming the multiple thin films of GMR sensor should be 10 nm or less.
In the process of creating such multiple thin films of GMR sensor, it was also found that the thickness of the photoresist pattern as a mask material for the etching has a great effect on the complete shape. As a result, it became apparent that it would be better if the photoresist pattern is formed by laminating a 0.01 to 0.05 μm thick organic film and a 0.1 to 0.35 μm thick resist film.
BRIEF DESCRIPTION OF THE DRAWINGS
Description will be made below about spin-valve giant magnetoresistive heads according to preferred embodiments of the present invention with reference to the accompanying drawings.
First Embodiment
The giant magnetoresistive thin films are patterned by etching such as ion milling method using a photoresist pattern as a mask pattern into multiple thin films of GMR sensor D1 to define the width of a reproducing track. The etching process can be controlled by an end point detector equipment, as is known in the art. Above the side inclined parts of the multiple thin films of GMR sensor D1 and the lower insulated gap layer 7, magnetic-domain control layers 9, base material layers 8 for the respective magnetic-domain control layers 9, conductive layers 11 and base material layers 10 for the respective conductive layers 11 are formed. The magnetic-domain control layers 9 is to align the magnetic orientation of the free magnetic layer 4 in such a direction that it intersects at right angles to the magnetic orientation of the pinned magnetic layer 2. The conductive layers 11 is to supply sensing current to the pinned magnetic layer 2, the nonmagnetic conductive layer 3 and the free magnetic layer 4 to sense a giant magnetic resistance change. An upper insulated gap layer 12 and an upper magnetic shield layer 13 are formed over the multiple thin films of GMR sensor D1 and the conductive layers 11.
The multiple thin films of GMR sensor D1 is arranged opposite to a magnetic recording medium to sense a very weak magnetic field from a minute single domain of the magnetic recording medium. In
To make sure of it, the amount of over etching was experimentally varied in the process of patterning the giant magnetoresistive thin films into the multiple thin films of GMR sensor D1 to obtain inclined angles of the end part of the free magnetic layer.
From this standpoint, trial manufacture models of elements were made by varying the amount of over etching to determine the probability of occurrence of an instable MR output waveform.
Making of high BPI accompanied with the demand for high recording density tends to narrow the gap between the upper and lower shield layers. Making the gap narrower means that the upper and lower insulated gap layers need to be made thinner. In particular, when the giant magnetoresistive thin films are over-etched to form the multiple thin films of GMR sensor, the portions directly under the magnetic-domain control layers are made thinner than the initial film thickness. This causes such a problem that the breakdown voltage between the lower magnetic shield layer and the giant magnetoresistive thin films becomes too small.
Our experiments reveled that when the gap between the upper and lower shield layers of single spin-valve type was 0.1 μm, the thickness of the lower insulated gap layer became 30 nm, when the gap between the upper and lower shield layers of dual spin-valve type was 0.12 μm, the thickness of the lower insulated gap layer became 30 nm. Therefore, the thickness of the lower insulated gap layer was set to 30 nm to determine values of the film thickness of the portions of the lower insulated gap layer directly under the magnetic-domain control layers and associated breakdown defect rates.
From the above-mentioned experimental results, it was found that the optimum spin-valve giant magnetoresistive head that meets both requirements of magnetic reliability for preventing instability of MR output voltage waveform and electrical reliability for securing breakdown voltage has such a structure that the amount of over etching is 10 nm or less and the inclined angles of the end parts of the free magnetic layer of GMR sensor is 45 degrees or more. To realize such a structure of the spin-valve giant magnetoresistive head, we went back to the principle of ion milling.
To manufacture the spin-value giant magnetoresistive head of
At this time, the resist film 16 may have a trapezoidal cross-sectional shape as shown in
Then, as shown in
The resist material forming the mask pattern M1 can be a photoresist capable of pattern formation of 0.35 μm or less thin resist film. For example, a resist having the property of permitting patterning with an exposure wavelength of 365 nm, 248 nm or 193 nm, or a resist having the property of permitting patterning with an electron beam.
The electron-beam lithography and the photolithography can also be used in combination. For example, a resist having the property of permitting patterning with a combination of the exposure wavelength of 365 nm and the electron beam, or a combination of the exposure wavelength of 248 nm and the electron beam can be used.
Second Embodiment
Our experiment on the dual spin-valve giant magnetoresistive head revealed that when the gap between the upper and lower shield layers was 0.12 μm, the initial thickness of the lower insulated gap layer became 30 nm.
Like in the first embodiment, it is found that the optimum spin-valve giant magnetoresistive head that meets both requirements of magnetic reliability for preventing instability of MR output voltage waveform and electrical reliability for securing breakdown voltage has such a structure that the amount of over etching OE to 10 nm or less and the end-part inclined angle of the free magnetic layer is 45 degrees or more. The head structure as shown in
Furthermore, in the embodiment, the horizontal distance DS between such a position that the thickness of the flat part of the magnetic-domain control layer becomes 99% and the end parts of the side faces in the middle line of the free magnetic layer was 157 nm. According to the embodiment, it is preferable that the distance DS is 200 nm or less.
Third EmbodimentThis embodiment is to use only a resist film 17 to form a mask pattern in the manufacturing process as shown in the first and second embodiments. The thickness of the resist film 17 is within a range of between 0.1 and 0.35 μm, and the mask pattern M3 can be formed in such an undercut shape that each lower part up to 0.05 μm in height from the bottommost face of the resist film 17 intrudes 0.05 to 0.15 μm inwardly in depth in parallel with the substrate.
The resist material forming the mask pattern M3 can be a photoresist capable of pattern formation of a 0.35 μm or less thin film. For example, a resist having the property of permitting patterning with an exposure wavelength of 365 nm, 248 nm or 193 nm, or a resist having the property of permitting patterning with an electron beam.
The electron-beam lithography and the photolithography can also be used in combination. For example, a resist having the property of permitting patterning with a combination of the exposure wavelength of 365 nm and the electron beam, or a combination of the exposure wavelength of 248 nm and the electron beam can be used.
Fourth EmbodimentThis embodiment is to use an organic film 14, an inorganic film 18 and a resist film 15 to form a mask pattern in the manufacturing process as shown in the first and second embodiments.
As shown in
The resist material forming the mask pattern M4 can be a photoresist capable of pattern formation of a 0.35 μm or less thin resist film. For example, a resist having the property of permitting patterning with an exposure wavelength of 365 nm, 248 nm or 193 nm, or a resist having the property of permitting patterning with an electron beam.
The electron-beam lithography and the photolithography can also be used in combination. For example, a resist having the property of permitting patterning with a combination of the exposure wavelength of 365 nm and the electron beam, or a combination of the exposure wavelength of 248 nm and the electron beam can be used.
As described above, according to the present invention, the amount of etching of the lower insulated gap layer, which is produced in the process of patterning the multiple thin films of GMR sensor in a trapezoidal cross-sectional shape is 10 nm or less. Further, the magnetic-domain control layers and the conductive layers are formed on both sides of the multiple thin films of GMR sensor, and the angle which the tangent line of each side face of the multiple thin films of GMR sensor to the middle line of the free magnetic layer in its thickness direction forms with respect to the middle line of the free magnetic layer is 45 degrees or more. This structure makes it possible to provide such a spin-valve giant magnetoresistive head that it meets both the requirements of magnetic reliability and electrical reliability for securing constant breakdown voltage and preventing instability of MR output voltage waveform.
Claims
1. A method of manufacturing a spin-valve giant magnetoresistive head comprising the steps of:
- forming a lower shield layer above a substrate;
- forming a lower insulated gap layer above said lower shield layer;
- forming multiple thin films above said lower insulated gap layer, said multiple thin films includes an antiferromagnetic layer, a pinned magnetic layer, a nonmagnetic conductive spacer, a free magnetic layer and a nonmagnetic protective layer;
- forming an organic film exhibiting a thickness within the range of 0.01 to 0.05 μm above said multiple thin films;
- forming an inorganic film exhibiting a thickness within the range of 0.1 to 0.30 μm;
- forming a desired resist mask pattern with a resist film exhibiting a thickness within the range of 0.1 to 0.35 μm;
- etching uncovered portions of said inorganic film under said resist mask pattern to form a desired pattern of said inorganic film; using the desired pattern of said inorganic film as a mask to etch uncovered portions of said multiple thin films under openings of the desired pattern of said inorganic film to pattern said multiple thin films into multiple thin films of GMR sensor;
- forming magnetic-domain control layers and conductive layers at both ends of said multiple thin films of GMR sensor; and
- removing said resist mask pattern to lift off said magnetic-domain control layers and said conductive layers.
2. A method of manufacturing a spin-valve giant magnetoresistive head comprising the steps of:
- forming a lower shield layer above a substrate;
- forming a lower insulated gap layer above said lower shield layer;
- forming multiple thin films above said lower insulated gap layer, said multiple thin films includes an antiferromagnetic layer, a pinned magnetic layer, a nonmagnetic conductive spacer, a free magnetic layer and a nonmagnetic protective layer;
- forming a desired resist mask pattern above said multiple thin films with a resist film exhibiting a thickness within the range of 0.1 to 0.35 μm;
- making said resist mask pattern in such an undercut shape that each lower part up to 0.05 μm in height from the bottommost face of said resist film intrudes 0.05 to 0.15 μm inwardly;
- etching uncovered portions of said multiple thin films under openings of said resist mask pattern to pattern said multiple thin films into multiple thin films of GMR sensor;
- forming magnetic-domain control layers and conductive layers at both ends of said multiple thin films of GMR sensor; and
- removing said resist mask pattern to lift off said magnetic-domain control layers and said conductive layers.
3. The method according to claim 1, wherein said resist film has the property of permitting resist patterning using light with an exposure wavelength of 365 nm.
4. The method according to claim 1, wherein said resist film has the property of permitting resist patterning using light with an exposure wavelength of 248 nm.
5. The method according to claim 1, wherein said resist film has the property of permitting resist patterning using light with an exposure wavelength of 193 nm.
6. The method according to claim 1, wherein said resist film has the property of permitting resist patterning using an electron beam.
7. The method according to claim 1, wherein said resist film has the property of permitting resist patterning using light with an exposure wavelength of 365 nm and an electron beam in combination.
8. The method according to claim 1, wherein said resist film has the property of permitting resist patterning using light with an exposure wavelength of 248 nm and an electron beam in combination.
9. The method according to claim 1, wherein said resist film has the property of permitting resist patterning using light with an exposure wavelength of 365 nm, the resist mask pattern having a trapezoidal cross-sectional shape with an angle of three degrees or more which each side face of said resist film forms with respect to the vertical direction.
10. The method according to claim 1, wherein said resist film has the property of permitting resist patterning using light with an exposure wavelength of 248 nm, the resist mask pattern having a trapezoidal cross-sectional shape with an angle of three degrees or more which each side face of said resist film forms with respect to the vertical direction.
11. The method according to claim 1, wherein said resist film has the property of permitting resist patterning using an electron beam, the resist mask pattern having a trapezoidal cross-sectional shape with an angle of three degrees or more which each side face of said resist film forms with respect to the vertical direction.
12. The method according to claim 1, wherein an end point detector equipment controls the amount of etching during etching of said multiple thin films.
13. A method of manufacturing a spin-valve giant magnetoresistive head comprising the steps of:
- forming multiple thin films of a GMR sensor including at least a lower shield layer, a lower insulated gap layer, an antiferromagnetic layer, a pinned magnetic layer formed on a border of the antiferromagnetic layer so that a magnetic orientation thereof is aligned in a fixed direction, a free magnetic layer, and a non-magnetic conductive spacer which achieves magnetic insulation between the pinned magnetic layer and the free magnetic layer;
- forming at both ends of the multiple thin films of the GMR sensor, magnetic-domain control layers operative to make the magnetic orientation of the free magnetic layer uniform, and conductive layers operative to supply current to the multiple thin films of the GMR sensor; and forming above the multiple thin films of the GMR sensor, an upper insulated gap layer and an upper magnetic shield layer;
- wherein the antiferromagnetic layer which is part of multiple thin films of GMR sensor is formed in at least one of a one layer and a two layer structure;
- wherein a read gap length indicative of a distance from the top of the lower shield layer and the bottom of the upper shield layer between which the multiple thin films of the GMR sensor are sandwiched is at least one of no greater than 0.1 μm and no greater than 0.12 μm; and
- wherein the angle which the tangent line of each side end face of the multiple thin films of the GMR sensor to the middle line of the free magnetic layer in a thickness direction thereof forms with respect to the middle line of the free magnetic layer is at least 45 degrees.
Type: Application
Filed: Dec 11, 2006
Publication Date: Apr 12, 2007
Inventors: Masatoshi Arasawa (Odawara), Haruko Tanaka (Nakai), Makoto Morijiri (Ninomiya), Koichi Nishioka (Hiratsuka), Shuichi Kojima (Hiratsuka), Masayasu Kagawa (Hiratsuka)
Application Number: 11/636,630
International Classification: G11B 5/127 (20060101);