Perpendicular magnetic recording medium

In a magnetic recording medium, there are realized an improvement in surface planarity and a reduction in characteristic degradation. The magnetic recording medium is fabricated so that the upper layer of a recording layer and a refill layer are formed of the same material.

CLAIM OF PRIORITY

The present application claims priority from Japanese application JP 2008-38163 filed on Feb. 20, 2008, the content of which is hereby incorporated by reference into this application.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a high-recording density magnetic recording device and, more particularly, to a magnetic recording medium of a hard disk unit.

2. Background Art

Along with an increase in the recording density of a magnetic recording device, noise due to an disorder in the magnetized state of track edges arising in association with an increase in track density, a side-read phenomenon arising due to reading from adjacent tracks, damage to a magnetic recording medium due to a decreased floating amount of a magnetic head, and the like have become extremely critical issues. In order to solve these problems, there is an expectation for the realization of a discrete track medium the tracks of which are physically divided from one another.

In recent years, a study has been made of a discrete track medium and there is known a variety of materials, processes and the like used to physically fill up intertrack spaces (see JP Patent Publication (Kokai) Nos. 2006-196143 and 2006-92632). Since a concavo-convex shape remains on a surface of a recording medium if a refill material is formed on a convex portion of a track and a concave portion between tracks, the medium surface needs to be planarized. As a method for removing superfluous layers of resist and the refill material on the convex portion, there is known a liftoff method for removing the resist and the refill material adhering to the periphery of the resist using an organic solvent. In addition, a dry etching method, CMP and the like capable of selectively removing only the refill material on the convex portion have been applied on trial. As the dry etching method, there is known a method in which, for example, a stopper layer is formed on a magnetic recording layer and the entire medium surface including a concavo-convex shape is filled with the refill material. Next, only a mask material is selectively dry-etched by taking advantage of a etching rate ratio between the refill material and the mask material, in order to remove a superfluous amount of refill material formed on convex portions (JP Patent Publication (Kokai) No. 2006-196143).

SUMMARY OF THE INVENTION

In a discrete track medium having a conventional structure, a magnetic recording layer is formed on predetermined tracks and desired magnetic characteristics are obtained by a photolithography step or a nanoimprint step, and an etching step, an intertrack filling step and a surface planarization step, when forming intertrack grooves including a continuous magnetic recording layer. As an example,FIG. 1illustrates a cross-sectional shape when a recording medium is cut in a track direction. A seed layer12, a soft underlayer13, a first intermediate layer14, a magnetic recording layer15, a refill layer19, a protective film21, and a lubricant layer20are laminated on a substrate11made of glass or the like. The width of the recording layer in a direction vertical to the film thickness direction thereof is defined as a track width41. In addition, according to, for example, JP Patent Publication (Kokai) No. 2006-196143, tracks are formed by ion beam etching, reactive ion beam etching or the like, using a resist formed by photolithography on a mask layer on the magnetic recording layer as a mask. This shape is formed by forming a resist pattern on the magnetic recording medium and performing ion beam etching using this resist pattern as a mask. After this, the resist is removed and a refill material is formed.

According to, for example, JP Patent Publication (Kokai) No. 2006-196143, an oxide film made of SiO2or the like formed by sputtering or a nonmagnetic metal is used as the refill material. Next, the substrate surface is planarized using ion beam etching, reactive ion etching (RIE) or the like, in order to remove superfluous portions of the refill material.

At the time of planarization, however, the conventional manufacturing method has had the following problems:deterioration in the planarity of the medium surface as a result of an etching rate difference being produced between convex and concave portions of the refill layer19;characteristic degradation in the upper portion of the magnetic recording layer due to argon ion collision in ion beam etching; andincrease in the number of manufacturing steps caused by inserting a stopper layer on the recording layer.

According to the present invention, the upper layer of the magnetic recording layer of a track and the refill layer are made of the same material, and an intermediate layer higher in etching rate than the refill material is inserted in the upper layer of the track. Thus, it is possible to planarize the medium surface when etching is finally completed.

After the magnetic recording layer is film-formed, a second intermediate layer16and a third intermediate layer17are film-formed sequentially using the same material as that of the refill material. Then, a resist layer47is laminated on the third intermediate layer17. Next, the resist layer47is processed into the shape of a resist pattern layer18for the purpose of track pattern formation. After patterning is performed on the third intermediate layer17, the second intermediate layer16and the magnetic recording layer15using this mask pattern, the resist pattern layer18is removed.

A refill material to be formed next is the same as that of the second intermediate layer16. Since the ion milling rate of the third intermediate layer17is approximately three times as fast as those of the refill layer19and the second intermediate layer16, the etching rate difference between concave and convex portions is adjusted. Thus, it is possible to realize an even more planar surface shape. In addition, there is no need for a stopper layer since the refill layer19and the second intermediate layer16are resistant to ion milling. Thus, it is possible to simplify a manufacturing process. Since the upper layer16of the magnetic recording layer15is a protective layer, it is also possible to reduce characteristic degradation due to argon ion collision. As a result, there are realized an improvement in surface planarity, a reduction in the number of manufacturing steps, and a reduction in characteristic degradation.

Firstly, the discrete track medium of the present invention makes it possible to enhance the planarity of a medium surface by forming the third intermediate layer17for adjusting the etching rate. Secondly, it is possible to reduce the number of manufacturing steps by forming the refill layer19, the protective layer21and the second intermediate layer16from the same material. In addition, it is possible to reinforce the discrete track medium against impact when a magnetic head collides with a magnetic disk.

EXPLANATION OF REFERENCE NUMERALS

14First intermediate layer

15Magnetic recording layer

16Second intermediate layer

17Third intermediate layer

18Resist pattern layer

30Three layers composed of seed layer12, soft underlayer13and first intermediate layer14

255Signal processing unit

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

In the best mode for carrying out the present invention, the upper layer of the magnetic recording layer of a track and the refill layer are made of the same material, and a coordination layer higher in etching rate than a refill material is inserted in the upper layer of the track.

Hereinafter, specific means for fabricating the magnetic recording medium of the present invention will be described usingFIG. 2.

As shown inFIG. 2A, a seed layer12, a soft underlayer13, a first intermediate layer14, a magnetic recording layer15, a second intermediate layer16, a third intermediate layer17, and a resist47are laminated on a substrate11.

The substrate11is made of glass, alumina, silicon or the like. The magnetic recording layer15is composed of, for example, a granular perpendicular recording medium formed of a Co, Cr and Pt-based alloy and a nonmagnetic substance, such as SiO2. The second intermediate layer16and the refill material19are made of diamond-like carbon (DLC) which is a nonmagnetic material. The thickness of the second intermediate layer16is preferably 3 nm or larger since the minimum film thickness for DLC to function as a protective layer is 3 nm. The third intermediate layer17is formed of, for example, SiO2or resist and is preferably have a thickness equal to or larger than the thickness of the second intermediate layer16. Hence, the film thickness of the third intermediate layer17is set to approximately 10 nm. As will be described later, the film thickness is set to 10 nm as a thickness with which planarity is finally reached, taking into consideration the etching rate difference between DLC and SiO2. Examples of the resist include a resist used for photoresist masks that can be subjected to exposure and patterning using electron beams and a resist used for nanoimprinting.

Next, as shown inFIG. 2B, patterning is performed on the resist layer47using an electron beam lithography method or a nanoimprint method, to form a resist pattern layer18.

Using a dry etching process such as ion beam etching, the structure of the resist pattern18is transferred onto the third intermediate layer17, the second intermediate layer16and the magnetic recording layer15, as shown inFIG. 2C, with the resist pattern18used as a mask. The magnetic recording layer can be etched using an ion beam etching method or a reactive ion etching (RIE) method.

The resist pattern18is removed by means of RIE, using an oxygen gas or the like, or ashing. If at this time, there is the re-deposition on the sidewalls of the resist18, third intermediate layer17, second intermediate layer16or magnetic recording layer15, the re-eposition may be removed by ion beam etching or the like.

The third intermediate layer17, if made of SiO2or the like, is resistant to an RIE gas used to remove the resist pattern18. Accordingly, the resist pattern18can be removed by an ion beam etching method using an etching gas containing an oxygen gas.

After this, as shown inFIG. 2D, a refill layer19is formed. As the material of the refill layer19, a material used for the second intermediate layer16is used. In the present embodiment, DLC, for example, can be mentioned as a candidate for the material. The thickness of the refill layer19is made to be larger than the sum of the thicknesses of the third intermediate layer17, second intermediate layer16and magnetic recording layer15, so that the refill material is fully buried in intertrack grooves and the refill layer19is flush with the second intermediate layer16when planarized and such that the surfaces of the refill material and the second intermediate layer are appeared alternatively.

SOG that can be hardened at or below such a temperature as not to degrade the magnetic recording characteristics or SiO2deposited by a sputtering method may be used as the refill layer19. In this case, however, the material of the third intermediate layer17serving as a coordination layer for adjusting the etching rate must be higher in ion beam etching rate than SOG or SiO2.

Next, the rugged surface of the third intermediate layer17is planarized using ion beam etching. In the case of ion beam etching, the incident angle of a beam is within the range of 80°±5°, assuming that the normal line of the substrate11is 0°.

The reason for the angle of etching in the step ofFIG. 2Dbeing within the range from 75° to 85° is that if the angle is smaller than 75°, a beam is projected in a similar manner onto both concave portions and convex portions. Thus, the third intermediate layer17is etched back with the concavo-convex shape thereof kept as is, resulting in a failure to planarize the surface. In addition, if the angle is larger than 85°, the beam is projected almost in parallel with the substrate. Thus, it is not possible to project the beam onto the entire area of the substrate.

At the time of etching, the glass substrate is spinning around an axis oriented in the direction of the substrate's normal line. As etching proceeds, the concavo-convex shape of the surface of the refill layer19approximates to planarity, as shown inFIG. 2E. When the corners of the third intermediate layer17begin to show up, the difference of elevation between concavities and convexities on the surface of the refill layer19is 7 or 8 nm. In consideration of a thickness at which etching is performed for planarization, the 10 nm-thick third intermediate layer17and the approximately 10 nm-thick refill layer19on the third intermediate layer17remain in track portions, and DLC is formed in intertrack groove portions to a thickness of approximately 13 nm. Since SiO2is three times higher in etching rate, when compared with DLC, convex portions are selectively etched. Thus, the time taken to etch the convex portions equals the time taken to etch the track portions and the intertrack groove portions. Consequently, it is possible to realize planarity, as shown inFIG. 2F.

The state of etching can be monitored during etching by means of Secondary Ion Mass Spectroscopy or the like. Accordingly, the third intermediate layer17may have the function as an etching monitor layer.

If Secondary Ion Mass Spectroscopy is carried out concurrently with ion beam etching, it is known, at the moment a signal from the third intermediate layer17disappears, that the surfaces of the second intermediate layer16and the refill layer19have aligned with each other. Accordingly, etching may be finished at this moment.

Since the second intermediate layer16is the same in etching rate as the refill layer19, the layers may be etched several nanometers further, so as not to expose the surface of the magnetic recording layer15(seeFIG. 2H).

As shown inFIG. 2F, the second intermediate layer16on the convex portions of the pattern and the intertrack refill material19that remain after the completion of ion beam etching may serve also as protective layers. For this reason, in the present invention, it is possible to omit a step of forming a protective layer following a planarization step.

A lubricant layer20made of a fluorine-based perfluoropolyether (PEPE) lubricant is coated on the medium surface using a dipping method when the refill layer19is planarized. This is because a refill material on the upper portion of the magnetic recording layer15has the function as a protective layer. The magnetic recording medium is thus completed, as shown inFIG. 2G.

In the same way as in embodiment 1, a magnetic recording medium is fabricated according to the steps ofFIGS. 2Athrough to2F.

If argon ions have impinged on the surface of the magnetic recording medium at the time of planarization and DLC of the uppermost surfaces of the second intermediate layer16and the refill layer19can no longer function as a protective layer, etching or ashing is performed up to a refill layer in the upper layer of the magnetic recording layer15, as shown inFIG. 2H, thereby uniformly removing the refill layer19and the second intermediate layer across the medium surface. Next, as shown inFIG. 21, a protective layer is once again formed to a thickness of 4 nm, and then a lubricant is coated thereon. Thus, it is possible to still maintain planarity.

Even if the DLC of the uppermost surfaces of the second intermediate layer16and the refill layer19suffers damage when planarization is performed using a chemical-mechanical polishing method (CMP) or gas cluster ion beams (GCIB), it is possible to also use the steps of embodiment 2.

FIG. 3is a schematic view illustrating one example of a magnetic disk unit using a magnetic disk of the present invention. This magnetic disk unit is configured with a magnetic disk250, a spindle motor251, a magnetic head252, an access arm253, an actuator254, a Signal processing unit255, and the like. A magnetic disk having a magnetic recording layer is rotated by the spindle motor251to write and read data using the magnetic head252. A magnetic head is located at the leading end of the access arm253, and the actuator254decides the magnetic head position of the radial direction on the magnetic disk.

The refill material19is made of DLC, which is a material conventionally used as a protective layer. There is a case that the leading end of the magnetic head252collides with the surface of the magnetic disk250when the magnetic disk250and the magnetic head252are actually in operation as a hard disk drive. Hence, there is concern that a structural distortion arising due to impact at this moment in the magnetic recording layer15, the first intermediate layer14, the soft underlayer13and the like may cause characteristic degradation. However, if intertrack spaces are filled with such a material as DLC having a high degree of hardness, the material has the function of reducing structural disorder cased by impact.

The present invention can also be applied to, for example, patterned media.