1. Field of the Invention
The present invention relates to a thin film magnetic head comprising a substrate made of an electrically insulating and non-magnetic material, and an inductive magnetic converting element including first and second magnetic films each having pole portions provided in the vicinity of an air bearing surface and being magnetically coupled at portions remote from the air bearing surface, a gap film arranged between the first and second magnetic films at least at the pole portions, and a thin film coil having a portion provided between said first and second magnetic films.
The present invention also relates to an inverted hybrid or composed type thin film magnetic head, in which an inductive magnetic recording element is provided on a substrate and a magnetoresistive reading element is arranged on the inductive recording element.
2. Related Art Statement
A hybrid type thin film magnetic head including a inductive recording element and a magnetoresistive reading element has been known from, for instance Japanese Patent Application Publication No. 59-35088 and U.S. Pat. No. 3,908,194. In this known thin film magnetic head, the magnetoresistive reading element is provided on a substrate and the inductive recording element is provided on the magnetoresistive reading element. However, this structure has various problems particularly in a view point of the mass production. Hereinafter, the inductive recording element is sometimes called the inductive element and the magnetoresistive reading element is often called the MR element for the sake of simplicity.
In the known structure in which the inductive element is provided on the MR element, the previously manufactured MR element is subjected to all process steps for manufacturing the inductive element. This causes a serious decrease in characteristics, reliability and manufacturing yield of the magnetic head.
In order to realize a hybrid type thin film magnetic head which can offer a high surface recording density, it is desirable to form the MR element by a giant magnetoresistive (GMR) film such as spin bulb film, super lattice film and granular film, instead of a normal anisotropic magnetoresistive film. Such a GMR film is liable to be damaged by a thermal treatment during the formation of the inductive element and an output of the MR element is reduced to a large extent. For instance, in a spin bulb film including an alternate stack of magnetic layers of Nixe2x80x94Fe and non-magnetic layers of Cu, at a temperature of about 200-250xc2x0 C. which is usually employed for manufacturing the inductive element, Ni and Cu atoms are mutually diffused and the stacking structure of the spin bulb film is destroyed.
An over-write property of the inductive element is largely dependent upon an apex angle of an coil supporting and isolating insulating film for supporting the thin film coil such that conductive turns thereof are isolated from each other, and upon a throat height of the pole portion. Therefore, in order to improve the stability, reliability and yield, it is very important to control precisely said apex angle and throat height.
Particularly, in order to improve the manufacturing yield of the thin film magnetic head, not only the above mentioned throat height of the inductive element, but also an MR height of the MR element have to be formed precisely. As is well known in the art, the throat height and MR height are determined by a position of the lowermost insulating layer of the coil supporting and isolating insulating film and a working precision of an air bearing surface which is opposed to a magnetic recording medium with a very small space during the recording and reading. For the sake of simplicity, hereinafter the air bearing surface is called ABS. In the known hybrid type thin film magnetic head having the inductive element formed on the MR element, in order to obtain desired throat height MR height precisely corresponding to designed values, it is necessary to perform a mask alignment for the formation of the lowermost insulating layer with a minimum alignment error with respect to the already formed MR film. However, the MR film has very small thickness such as several hundreds xc3x85 and a pole portion of a relatively thick first magnetic film of the inductive element is formed on the MR film, a contour of the MR film could not be seen clearly during the mask alignment. Therefore, the precise mask alignment for the lowermost insulating layer could be carried out only with difficulty. It should be noted that the mask alignment for the lowermost insulating layer is also important for obtaining a desired throat height.
In order to mitigate the above problem of the mask alignment, an alignment pattern may be formed and the mask alignment may be performed with respect to this pattern. However, in this case, an alignment error of the alignment pattern is introduced, and thus the mask alignment for the lowermost insulating layer could not be carried out precisely. Furthermore, the manufacturing process becomes complicated and cost is increased.
Usually the thin film coil has a plurality of desired properties are wasted after a polishing process for forming the ABS.
The known hybrid type thin film magnetic head has encountered another problem. Since after the MR film has been formed, a shield gap film is formed and then a first magnetic film of the inductive element is formed on the shield gap film, a pole portion of the first magnetic film could not have a flat surface due to the MR film and shield gap film. When a second magnetic film is formed on the first magnetic film via the writing gap film, the pole portion of the second magnetic film also could not have a flat surface. Such non-flat pole portions results in a degradation in a high frequency property of the inductive recording element. In order to avoid such a degradation, in the known manufacturing method, after forming the first magnetic film, a planarizing process is performed by a chemical-mechanical polishing (CMP) which has been known in the semiconductor device manufacturing technique. This planarizing process apparently increases the manufacturing cost and time.
In Japanese Patent Laid-open Publication Kokai Hei 3-263603, there is proposed a inverted or reversed type thin film magnetic head, in which a magnetoresistive reading element is formed on an inductive recording element. However, this prior art publication does not teach a structure suitable for alignment between the MR element and the photoresist coil layers, and after a coil layer is formed, its insulating layer, e.g. photoresist is subjected to a heat treatment at a temperature of about 250xc2x0 C. for forming a flat surface. This flat surface of the insulating layer is required for forming a next coil layer. During this heating process, the photoresist is softened or melt and its pattern size is varied largely. Moreover, when a patterning for forming a coil layer is conducted by milling, a pattern of the coil supporting and isolating insulating film constituting a positional reference for the MR element is etched again, and the retardation of pattern occurs. When such a variation of the pattern in the insulating layer occurs, even if the photomask for the photoresist is aligned precisely, a positional relationship of the photoresist with respect to the MR element might be changed. The variation of the photoresist pattern might amount to 0.5-0.6 xcexcm when a thickness of the photoresist is large. Particularly, a hybrid type thin film magnetic head for high frequency has been required to have the throat height not longer than 1.00 xcexcm. Therefore, it is necessary to control precisely the variation of the photoresist pattern in the order to sub-microns.
The known technique including a large variation in the photoresist pattern could not meet such a requirement, and many thin film magnetic heads whose inductive and/or magnetoresistive element have not supporting the thin film coil, and does not disclose a useful technique for suppressing the variation of the photoresist pattern.
Moreover, in the thin film magnetic head including the inductive recording element, in order to attain a high surface record density as well as an excellent high frequency property, it is necessary to minimize a width of the pole portions of first and second magnetic films. For instance, in Japanese Patent Application Laid-open Publication, Kokai Hei 3-263603, there is described a method of minimizing a width of the pole portions of the first and second magnetic films. In this known method, after the ABS has been obtained by polishing, tips of the pole portions of the first and second magnetic films exposing to the ABS are etched to reduce a width of the pole portions. However, such a known method could not be practically used. In order to manufacture thin film magnetic heads on a mass scale in an efficient manner, a width of the pole portions of first and second magnetic films has to be minimized during the manufacture of the inductive element.
In the thin film magnetic film of the type mentioned above, in order to attain a stability of floating posture, to increase the number of thin film magnetic heads which can be manufactured from a single wafer, and to minimize a size of the thin film magnetic head, it is advantageous to reduce a size of a slider as is taught in Japanese Patent Application Laid-open Publication Kokai-Sho 64-21713 and U.S. Pat. No. 4,928,195. However, even if a size of the slider is reduced, each of bonding pads provided on the slider for connecting the magnetic head to an external circuit must have a sufficient surface area for firmly connecting a lead wire thereto. In the hybrid type thin film magnetic head comprising a stack of the inductive recording element and magnetoresistive reading element, it is necessary to provide two bonding pads connected to both ends of a thin film coil and two bonding pads connected to both ends of the MR film. These bonding pads prevent the miniaturization of the slider.
In Japanese Utility Model Application Publication 7-31362, there is described an inductive type thin film magnetic head, in which lead conductors are extended up to a side wall of a slider and bonding pads are formed on the lead conductors. However, this structure is not suitable for the miniaturization of the slider, because the lead conductors require a relatively large surface area. In this publication, there is further disclosed that a part of a plurality of bonding pads are position above the magnetic converting element. However, the prior art publication does not teach anything about the hybrid type thin film magnetic head having a stack structure of the inductive recording element and magnetoresistive reading element.
The present invention has for its object to provide a novel and useful hybrid type thin film magnetic head, in which a magnetoresistive reading element is not affected by processes for manufacturing an inductive recording element.
It is another object of the invention to provide a hybrid type thin film magnetic head having a high surface record density, in which a magnetoresistive element is formed by a giant magnetoresistive film such as spin bulb film, super lattice film and granular film, said giant magnetoresistive film is not subjected to a thermal damage.
It is another object of the invention to provide a hybrid type thin film magnetic head, in which apex angle and throat height of a pole portion can be controlled precisely.
It is another object of the invention to provide a hybrid type thin film magnetic head, in which a throat height of an inductive recording element and an MR height of an MR element can be set to desired values.
It is another object to provide a hybrid type thin film magnetic head, in which undesired variation of a photoresist for insulating a thin film coil due to a heating treatment can be avoided, a throat height can be minimized and various dimensions can be precisely controlled to have an excellent high frequency property.
It is another object of the invention to provide a hybrid type thin film magnetic head, in which undesired variation of a photoresist pattern due to a milling process for forming a thin film coil can be avoided and a throat height can be minimized to obtain an excellent high frequency property.
It is another object of the invention to provide a hybrid type thin film magnetic head, in which a flat first magnetic film of an inductive recording element can be formed without using the chemical-mechanical polishing, and the deterioration of the high frequency property due to the non-flat first magnetic film can be avoided.
It is still another object of the invention to provide a thin film magnetic head including at least an inductive recording element, in which a width of a pole portion can be minimized to improve the surface recording density and high frequency property.
It is another object of the invention is to provide a thin film magnetic head including at least an inductive recording element, in which a width of a pole portion can be minimized without making a manufacturing process complex, cumbersome and expensive.
It is another object of the invention to provide a thin film magnetic head including at least an inductive recording element, in which a width of a pole portion of a minimized size can be formed uniformly.
It is another object of the invention to provide a thin film magnetic head including at least an inductive recording element, in which a magnetic field is confined in a pole portion to improve the high frequency property and surface recording density.
It is still another object of the invention to provide a hybrid type thin film magnetic head, which can be easily miniaturized so that the number of magnetic heads which can be formed from a single wafer can be increased and a magnetic disc device using the magnetic head can be also miniaturized, and the magnetic head can float above a magnetic disc in a stable manner.
The present invention also relates to a method of manufacturing a thin film magnetic head and has an object to provide a novel and useful method by means of which the above mentioned thin film magnetic head according to the invention can be manufactured in a precise, efficient and less expensive manner.
According to a first aspect of the invention, a hybrid type thin film magnetic head comprises:
a substrate made of a non-magnetic insulating material and having a surface in which a recessed portion is formed;
an inductive recording element formed to be supported by said substrate; and
a magnetoresistive reading element formed to be supported by said inductive recording element;
wherein said inductive recording element includes:
a first magnetic film having a portion formed on an inner surface of said recessed portion and a pole portion formed on said surface of the substrate to extend from said portion formed on the inner surface of the recessed portion up to an air bearing surface;
a thin film coil formed within said recessed portion and having a plurality of conductive coil turns;
a coil supporting and isolating insulatin formed within said recessed portion such that conductive turns of the thin film coil are su and isolated by said insulating film;
a gap film made of a non-magnetic material formed at least on said pole portion of the first magnetic film;
a second magnetic film formed on said gap film and having a pole portion which is opposed to said pole portion of the first magnetic film via said gap film and a portion which is magnetically coupled with said first magnetic film at a position remote from said pole portion; and
said magnetoresistive reading element includes:
a first shield gap film made of a non-magnetic insulating material and formed on said second magnetic film;
a magnetoresistive film formed on said first shield gap film such that a side edge of the magnetoresistive film is exposed on said air bearing surface;
a second shield gap film made of a non-magnetic insulating material and formed on the magnetoresistive film and first shield gap film; and
a third magnetic film formed on said second shield gap film.
According to the first aspect of the invention, a method of manufacturing an inverted hybrid type thin film magnetic head including an inductive recording element, a magnetoresistive reading element, and a substrate supporting said inductive recording element and magnetoresistive reading element, comprises the steps of:
forming a recessed portion in a surface of a substrate;
forming a first magnetic film on an inner surface of said recessed portion and on a portion of said surface of the substrate such that said first magnetic film includes a pole portion extending from the recessed portion up to an air bearing surface;
forming a thin film coil having a plurality of conductive coil turns within said recessed portion such that said conductive coil turns are supported and isolated from each other by means of a coil supporting and isolating insulating film formed within said recessed portion;
forming a gap film made of a non-magnetic material at least on said pole portion of the first magnetic film;
forming a second magnetic film on said gap film such that the second magnetic film includes a pole portion which is opposed to said pole portion of the first magnetic film via said gap film and a portion which is magnetically coupled with said first magnetic film at position remote from said pole portion;
forming a first shield gap film on said second magnetic film;
forming a magnetoresistive film on said first shield gap film;
forming a second shield gap film on the magnetoresistive film and first shield gap film; and
forming a third magnetic film on said second shield gap film.
According to the first aspect of the invention, since the magnetoresistive reading element is formed on the inductive recording element, it is possible to manufacture the magnetoresistive reading element after the inductive recording element has been formed. Therefore, the magnetoresistive reading element can be effectively prevented from being affected by a process for manufacturing the inductive recording element.
As stated above, according to the first aspect of the invention, the magnetoresistive reading element is not affected by a heating treatment for forming the thin film coil isolated by the coil supporting and isolating insulating film. Therefore, the magnetoresistive film may be advantageously formed by a GMR film such as spin bulb film, super lattice film and granular film which is liable to be damaged by a high temperature annealing process during the formation of the inductive recording element. In this manner, it is possible to obtain the magnetoresistive reading element having a very high sensitivity.
According to the first aspect of the invention, the thin film coil and coil supporting and isolating insulating film are formed within the recessed portion formed in the surface of the substrate, and thus the apex angle and throat height can be precisely controlled by adjusting an angle and a configuration of a side wall of the recessed portion and a depth of the recessed portion.
The first magnetic film has the pole portion which extends from a portion of the first magnetic film formed on the surface of the recessed portion, and thus there is formed a corner between the pole portion and the portion formed on the recessed portion. The throat height is determined with reference to said corner whose position is not changed during the formation of the magnetic head. Therefore, the throat height can be precisely set to a desired value.
The thin film coil is usually formed by a stack of a plurality of coil turn layers which are isolated by a plurality of insulating layers of the coil supporting and isolating insulating film, and the insulating layers are usually made of a photoresist. In order to form successive coil turn layers precisely, an insulating layer is subjected to a heating treatment at a temperature of about 250xc2x0 C. at which the photoresist of the insulating layer is softened or melt. However, according to the invention, the thin film coil and coil supporting and isolating insulating film are formed within the recessed portion, even if the photoresist is softened or melt, the configuration of the thin film coil and coil supporting and isolating insulating film is not changed, but is fixed in accordance with a configuration of the recessed portion. Therefore, the photoresist pattern is not changed under the heating treatment. Moreover, the coil supporting and isolating insulating film pattern is not changed even by a process for milling the coil supporting and isolating insulating film during the formation of the coil turns of the thin film coil. Therefore, according to the invention, the apex angle can be precisely determined by the inclination angle and configuration of the side wall of the recessed portion and the throat height can be also precisely determined with reference to the corner of the first magnetic head.
According to a second aspect of the invention, a thin film magnetic head comprises:
a substrate having a surface; and
an inductive recording element formed on said surface of the substrate;
wherein said inductive recording element includes:
a first magnetic film formed on said substrate and having a pole portion extending from an air bearing surface;
a thin film coil having a plurality of conductive coil turns each of which includes a portion formed on said first magnetic film;
a coil supporting and isolating insulating film formed to isolate said conductive coil turns of the thin film coil are isolated from each other;
a gap film made of a non-magnetic material and having a pole portion which is opposed to said pole portion of the first magnetic film; and
a second magnetic film having a pole portion which is opposed to said pole portion of the first magnetic film via said gap film and a portion which is magnetically coupled with said first magnetic film at position remote from said pole portion, said pole portion of the second magnetic film being constituted by a protrusion which is formed in a surface of the second magnetic film contacted with said gap film and protrudes toward said pole portion of the first magnetic film.
According to the second aspect of the invention, a method of manufacturing a thin film magnetic head including a substrate having and an inductive recording element formed on said substrate, comprises the steps of:
forming a recessed portion and a groove in a surface of the substrate such that said groove extends from said recessed portion up to an air bearing surface;
forming a first magnetic film on an inner surface of said recessed portion and within said groove of the substrate;
etching a part of said first magnetic film formed within said groove to form a pole portion within the groove such that a surface level of the pole portion of the first magnetic film within the groove is lower than a surface level of the substrate in which said groove is formed such that said groove has a space therein;
forming a thin film coil having a plurality of conductive coil turns within said recessed portion such that said conductive coil turns are isolated from each other by means of a coil supporting and isolating insulating film formed within said recessed portion;
forming a gap film made of a non-magnetic material on said coil supporting and isolating insulating film formed in said recessed portion and on said pole portion of the first magnetic film within said groove, said gap film having a thickness which is smaller than a depth of said space within the groove such that the groove still has a space;
forming a second magnetic film on said gap film such that said second magnetic film includes a pole portion constituted by a protrusion which projects into said space of the groove and is opposed to said pole portion of the first magnetic film via said gap film, and a portion which is magnetically coupled with said first magnetic film at a position remote from said pole portion.
According to the second aspect of the invention, a method of manufacturing a thin film magnetic head including a substrate having and an inductive recording element formed on said substrate, comprises the steps of:
forming a recessed portion in a surface of the substrate;
forming a first magnetic film on an inner surface of said recessed portion and on said surface of the substrate such that the first magnetic film has a pole portion which extends from said recessed portion up to an air bearing surface;
forming a thin film coil having a plurality of conductive coil turns within said recessed portion such that said conductive coil turns are supported and isolated by a coil supporting and isolating insulating film formed within said recessed portion, a surface level of said coil supporting and isolating insulating film being not higher than a surface level of the pole portion of the first magnetic film;
forming an inorganic insulating film on said substrate, said pole portion of the first magnetic film and said coil supporting and isolating insulating film;
etching said inorganic insulating film such that a surface of said pole portion of the first magnetic film is exposed;
etching said exposed surface of the pole portion of the first magnetic film such that a surface level of the pole portion of the first magnetic film is lower than a surface level of the inorganic film so as to form a groove;
forming a gap film made of a non-magnetic material on said inorganic insulating film and on said pole portion of the first magnetic film within said groove;
forming a second magnetic film on said gap film such that said second magnetic film includes a pole portion constituted by a protrusion which projects into said groove and is opposed to said pole portion of the first magnetic film via said gap film, and a portion which is magnetically coupled with said first magnetic film at a position remote from said pole portion.
According to the second aspect of the invention, a method of manufacturing a thin film magnetic head including a substrate having and an inductive recording element formed on said substrate, comprises the steps of:
forming a recessed portion in a surface of the substrate;
forming a first magnetic film on an inner surface of said recessed portion and on said surface of the substrate such that the first magnetic film has a pole portion which extends from said recessed portion up to an air bearing surface;
forming a metal film at least on said pole portion of the first magnetic film, said metal film being made of a metal which has an etching property different from that of the first magnetic film;
forming a thin film coil having a plurality of conductive coil turns within said recessed portion such that said conductive coil turns are supported and isolated by a coil supporting and insulating film formed within said recessed portion, a surface level of said coil supporting and isolating insulating film being lower than a surface level of the metal film;
forming an inorganic insulating film on said substrate, said metal film on the pole portion of the first magnetic film and said coil supporting and isolating insulating film;
etching said inorganic insulating film such that a surface of said metal film is exposed;
selectively etching said metal film to expose the surface of the pole portion of the first magnetic film such that a surface level of the pole portion of the first magnetic film is lower than a surface level of the inorganic insulating film so as to form a groove;
forming a gap film made of a non-magnetic material on said inorganic insulating film and on said pole portion of the first magnetic film within said groove;
forming a second magnetic film on said gap film such that said second magnetic film includes a pole portion constituted by a protrusion which projects into said groove and is opposed to said pole portion of the first magnetic film via said gap film, and a portion which is magnetically coupled with said first magnetic film at a position remote from said pole portion.
According to the above mentioned second aspect of the invention, a width of a writing pole can be minimized to a width of said protrusion of the second magnetic film, and thus a high surface recording density can be attained and a high frequency property can be improved.
Moreover, said protrusion is formed by a part of a whole thickness of the second magnetic film, a magnetic flux is effectively confined at the writing pole, which can improve the surface recording density and high frequency property.
Furthermore, a width of said protrusion can be formed precisely and finely by using a high precision patterning technique mainly a photolithography during the manufacturing process of the second magnetic film.
It should be noted that although it is not necessary to constitute the thin film magnetic head according to the second aspect of the invention as the hybrid type thin film magnetic head, it is advantageous to constitute the thin film magnetic head according to the second aspect of the invention as the hybrid type one including a magnetoresistive reading element in addition to the inductive recording element. In such a case, it is particularly advantageous to construct the hybrid type thin film magnetic head as the inverted structure like as the first aspect of the invention. In this case, since the second magnetic film can be formed on a planar surface of the gap film, said protrusion constituting the writing pole can be also formed precisely.
According to a third aspect of the invention, an inverted hybrid type thin film magnetic head comprises:
a substrate having a surface in which a recessed portion is formed;
an inductive recording element formed to be opposed to said surface of the substrate in which said recessed portion is formed; and
a magnetoresistive reading element formed on a side of said inductive recording element which is opposite to said substrate;
wherein said inductive recording element includes:
a first magnetic film formed on said recessed portion of the substrate and having a pole portion which is formed on the substrate and extends from the recessed portion up to an air bearing surface;
a thin film coil formed within said recessed portion and having a plurality of conductive turns;
a coil supporting and isolating insulating film formed within said recessed portion such that said conductive turns of the thin film coil are supported and isolated by said coil supporting and isolating insulating film;
a gap film made of a non-magnetic material formed at least on said pole portion of the first magnetic film;
a second magnetic film formed on said gap film and having a pole portion which is opposed to said pole portion of the first magnetic film via said gap film and a portion which is magnetically coupled with said first magnetic film at position remote from said pole portion; and
two conductors each having one ends connected to respective ends of said thin film coil;
said magnetoresistive reading element includes:
a first shield gap film formed on said second magnetic film;
a magnetoresistive film formed on said first shield gap film such that a side edge of the magnetoresistive film is exposed on said air bearing surface;
a second shield gap film formed on the magnetoresistive film and first shield gap film; and
a third magnetic film formed on said second shield gap film and having a portion which is opposed to said magnetoresistive film via said second shield gap film; and
at least two bonding pads formed on a side wall of said substrate on a side from which a bearing air flow exits, one of said bonding pads being connected to one of said two conductors which is connected to one end of the thin film coil and being provided above the thin film coil such that a center of the relevant bonding pad situates within a pattern of the thin film coil.
According to the third aspect of the invention, a method of manufacturing a hybrid type thin film magnetic head including an inductive recording element, a magnetoresistive reading element, and a substrate supporting said inductive recording element and magnetoresistive reading element, comprising the steps of:
forming a depressed portion in a surface of a substrate;
forming a first magnetic film on an inner surface of said recessed portion of the substrate and on a portion of said surface of the substrate such that said first magnetic film includes a pole portion extending from the recessed portion up to an air bearing surface;
forming a thin film coil having a plurality of conductive turns within said recessed portion such that said conductive coil turns are isolated from each other by means of a first insulating film formed within said recessed portion;
forming a gap film made of a non-magnetic material at least on said pole portion of the first magnetic film and said second insulating film;
forming a second magnetic film on said gap film such that the second magnetic film includes a pole portion which is opposed to said pole portion of the first magnetic film via said gap film and a portion which is magnetically coupled with said first magnetic film at position remote from said pole portion;
forming a first shield gap film on said second magnetic film at least at a portion near the air bearing surface;
forming a magnetoresistive film on said first shield gap film;
forming a second shield gap film on the magnetoresistive film and first shield gap film;
forming a third magnetic film on said second shield gap film at least at a portion which is opposed to said magnetoresistive film via said second shield gap film;
forming a second insulating film on said third magnetic film and second shield gap film;
forming first and second pairs of conductors, said first pair of conductors being connected to respective ends of said thin film coil through via holes formed in said second insulating film and said second pair of conductors being connected to respective ends of said magnetoresistive film by means of via holes formed in said second insulating film; and
forming first and second pairs of bonding pads on said second insulating film, said first pair of bonding pads being connected to said first pair of conductors, said second pair of bonding pads being connected to said second pair of conductors, and one of said first pair of bonding pads being formed such that a center of the relevant bonding pad situates within a plane of a pattern defined by said thin film coil.
In the thin film magnetic head according to the third aspect of the invention, in addition to all the above mentioned merits of the thin film magnetic head according to the first aspect of the invention, the following merits can be obtained.
Since one of the bonding pads connected to the one end of the thin film coil is provided on the side wall of the substrate at such a position that its center situates within the pattern defined by the thin film coil, a surface area of the side wall of the substrate can be utilized efficiently. Therefore, a surface area of the substrate can be reduced, and thus the thin film magnetic head can be minimized. This results in that a floating posture of the magnetic head above a magnetic record medium can be stabilized, a magnetic disc device using the thin film magnetic head can be also minimized, and a larger number of magnetic heads can be manufactured from a single wafer.
In a preferable embodiment of the thin film magnetic head according to the third aspect of the invention, two further bonding pads each connected to respective ends of the magnetoresistive film are also provided on the side wall of the substrate such that all four bonding pads are aligned in a direction which is perpendicular to a direction of the bearing air flow.
According to a fourth aspect of the invention, a hybrid type thin film magnetic head comprises:
a substrate having a surface in which a recessed portion is formed;
an inductive recording element formed to be opposed to said surface of the substrate in which said recessed portion is formed; and
a magnetoresistive reading element formed on a side of said inductive recording element which is opposite to said substrate;
wherein said inductive recording element includes:
a first magnetic film formed on said recessed portion of the substrate and having a pole portion extending from the recessed portion up to an air bearing surface;
a thin film coil formed within said recessed portion and having a plurality of conductive turns;
an insulating film formed within said recessed portion such that said conductive turns of the thin film coil are isolated by said insulating film;
a gap film made of a non-magnetic material formed at least on said pole portion of the first magnetic film and said insulating film;
a second magnetic film having a pole portion which is opposed to said pole portion of the first magnetic film via said gap film and a portion which is magnetically coupled with said first magnetic film at position remote from said pole portion, said pole portion of the second magnetic film being constituted by a protrusion which is formed in a surface of the second magnetic film contacted with said gap film and protrudes toward said pole portion of the first magnetic film; and
two conductors each having one ends connected to respective ends of said thin film coil; said magnetoresistive reading element includes:
a first shield gap film formed on said second magnetic film;
a magnetoresistive film formed on said first shield gap film such that a side edge of the magnetoresistive film is exposed on said air bearing surface;
a second shield gap film formed on the magnetoresistive film and first shield gap film; and
a third magnetic film formed on said second shield gap film and having a portion which is opposed to said magnetoresistive film via said second shield gap film; and
at least two bonding pads formed on a side wall of said substrate on a side from which a bearing air flow exits, one of said bonding pads being connected to one of said two conductors which is connected to one end of the thin film coil and being provided above the thin film coil such that a center of the relevant bonding pad situates within a plane of a pattern defined by the thin film coil.
According to the fourth aspect of the invention, a method of manufacturing a hybrid type thin film magnetic head including a substrate having, an inductive recording element formed on said substrate and a magnetoresistive reading element formed on the inductive recording element, comprises the steps of:
forming a recessed portion and a groove in a surface of the substrate such that said groove extends from said recessed portion up to an air bearing surface;
forming a first magnetic film on an inner surface of said recessed portion and on an inner surface of said groove of the substrate;
etching a part of said first magnetic film formed on the inner surface of said groove to form a pole portion within the groove such that a surface level of the pole portion of the first magnetic film within the groove is lower than a surface level of the substrate in which said groove is formed so that a step is formed between these surfaces;
forming a thin film coil having a plurality of conductive coil turns within said recessed portion such that said conductive coil turns are isolated from each other by means of a first insulating film formed within said recessed portion;
forming a gap film made of a non-magnetic material on said insulating film formed in said recessed portion and said pole portion of the first magnetic film such that the gap film includes a step corresponding to said step of the first magnetic film;
forming a second magnetic film on said gap film such that said second magnetic film includes a pole portion constituted by a protrusion which is formed within said groove and is opposed to said pole portion of the first magnetic film via said gap film and a portion which is magnetically coupled with said first magnetic film at position remote from said pole portion;
forming a first shield gap film on said second magnetic film at least at a portion near the air bearing surface;
forming a magnetoresistive film on said first shield gap film;
forming a second shield gap film on the magnetoresistive film and first shield gap film;
forming a third magnetic film on said second shield gap film at least at a portion which is opposed to said magnetoresistive film via said second shield gap film;
forming a second insulating film on said third magnetic film and second shield gap film;
forming first and second pairs of conductors, said first pair of conductors being connected to respective ends of said thin film coil through via holes formed in said second insulating film and said second pair of conductors being connected to respective ends of said magnetoresistive film by means of via holes formed in said second insulating film; and
forming first and second pairs of bonding pads on said second insulating film, said first pair of bonding pads being connected to said first pair of conductors, said second pair of bonding pads being connected to said second pair of conductors, and one of said first pair of bonding pads being formed such that a center of the relevant bonding pad situates within a plane of a pattern defined by said thin film coil.
According to the fourth aspect of the invention, a method of manufacturing a hybrid type thin film magnetic head including a substrate having, an inductive recording element formed on said substrate, and a magnetoresistive reading element formed on the inductive recording element comprises the steps of:
forming a recessed portion in a surface of the substrate;
forming a first magnetic film on an inner surface of said recessed portion and on said surface of the substrate such that the first magnetic film has a pole portion which extends from said recessed portion up to an air bearing surface;
forming a thin film coil having a plurality of conductive coil turns within said recessed portion such that said conductive coil turns are supported and isolated by a coil supporting and isolating insulating film formed within said recessed portion, a surface level of said coil supporting and isolating insulating film being not higher than a surface level of the pole portion of the first magnetic film;
forming an inorganic insulating film on said substrate, said pole portion of the first magnetic film and said coil supporting and isolating insulating film;
etching said inorganic insulating film such that a surface of said pole portion of the first magnetic film is exposed;
etching said exposed surface of the pole portion of the first magnetic film such that a surface level of the pole portion of the first magnetic film is lower than a surface level of the inorganic film so as to form a groove;
forming a gap film made of a non-magnetic material on said inorganic insulating film and on said pole portion of the first magnetic film within said groove;
forming a second magnetic film on said gap film such that said second magnetic film includes a pole portion constituted by a protrusion which projects into said groove and is opposed to said pole portion of the first magnetic film via said gap film, and a portion which is magnetically coupled with said first magnetic film at a position remote from said pole portion;
forming a first shield gap film on said second magnetic film at least at a portion near the air bearing surface;
forming a magnetoresistive film on said first shield gap film;
forming a second shield gap film on the magnetoresistive film and first shield gap film;
forming a third magnetic film on said second shield gap film at least at a portion which is opposed to said magnetoresistive film via said second shield gap film;
forming a second insulating film on said third magnetic film and second shield gap film;
forming first and second pairs of conductors, said first pair of conductors being connected to respective ends of said thin film coil through via holes formed in said second insulating film and said second pair of conductors being connected to respective ends of said magnetoresistive film by means of via holes formed in said second insulating film; and
forming first and second pairs of bonding pads on said second insulating film, said first pair of bonding pads being connected to said first pair of conductors, said second pair of bonding pads being connected to said second pair of conductors, and one of said first pair of bonding pads being formed such that a center of the relevant bonding pad situates within a plane of a pattern defined by said thin film coil.
According to the fourth aspect of the invention, a method of manufacturing a hybrid type thin film magnetic head including a substrate having, an inductive recording element formed on said substrate, and a magnetoresistive reading element formed on the inductive recording element comprises the steps of:
forming a recessed portion in a surface of the substrate;
forming a first magnetic film on an inner surface of said recessed portion and on said surface of the substrate such that the first magnetic film has a pole portion which extends from said recessed portion up to an air bearing surface;
forming a metal film at least on said pole portion of the first magnetic film, said metal film being made of a metal which has an etching property different from that of the first magnetic film;
forming a thin film coil having a plurality of conductive coil turns within said recessed portion such that said conductive coil turns are supported and isolated by a coil supporting and insulating film formed within said recessed portion, a surface level of said coil supporting and isolating insulating film being lower than a surface level of the metal film;
forming an inorganic insulating film on said substrate, said metal film on the pole portion of the first magnetic film and said coil supporting and isolating insulating film;
etching said inorganic insulating film such that a surface of said metal film is exposed;
selectively etching said metal film to expose the surface of the pole portion of the first magnetic film such that a surface level of the pole portion of the first magnetic film is lower than a surface level of the inorganic insulating film so as to form a groove;
forming a gap film made of a non-magnetic material on said inorganic insulating film and on said pole portion of the first magnetic film within said groove;
forming a second magnetic film on said gap film such that said second magnetic film includes a pole portion constituted by a protrusion which projects into said groove and is opposed to said pole portion of the first magnetic film via said gap film, and a portion which is magnetically coupled with said first magnetic film at a position remote from said pole portion.
forming a first shield gap film on said second magnetic film at least at a portion near the air bearing surface;
forming a magnetoresistive film on said first shield gap film;
forming a second shield gap film on the magnetoresistive film and first shield gap film;
forming a third magnetic film on said second shield gap film at least at a portion which is opposed to said magnetoresistive film via said second shield gap film;
forming a second insulating film on said third magnetic film and second shield gap film;
forming first and second pairs of conductors, said first pair of conductors being connected to respective ends of said thin film coil through via holes formed in said second insulating film and said second pair of conductors being connected to respective ends of said magnetoresistive film by means of via holes formed in said second insulating film; and
forming first and second pairs of bonding pads on said second insulating film, said first pair of bonding pads being connected to said first pair of conductors, said second pair of bonding pads being connected to said second pair of conductors, and one of said first pair of bonding pads being formed such that a center of the relevant bonding pad situates within a plane of a pattern defined by said thin film coil.
In the thin film magnetic head according to the fourth aspect of the invention, all the above mentioned merits of the thin film magnetic heads according to the above mentioned first, second and third aspects of the invention can be attained.