Abstract:
A method of fabricating a discrete track magnetic recording media. A base layer is provided onto which repeating and alternating magnetic layer and non-magnetic layers are deposited. The thickness of the magnetic layer corresponds to the width of the track of the recording media. A cylindrical rod can be used as the base layer, such that the alternating magnetic and non-magnetic layers spiraling or concentric layers around the rod. The resulting media layer can be cut or sliced into individual magnetic media or used to imprint other media discs with the discrete pattern of the media layer.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
       [0001]    This application is a divisional of U.S. application Ser. No. 12/178,443 filed Jul. 23, 2008, which is incorporated herein by reference in its entirety. 
     
    
     BACKGROUND 
       [0002]    Thin film magnetic recording disks generally comprise a disk substrate having a magnetic layer and a number of underlayers and overlayers deposited thereon. The nature and composition of each layer is selected to provide desired magnetic recording characteristics, as generally recognized in the industry. An exemplary present day thin film disk comprises a non-magnetic disk substrate, typically composed of an aluminum alloy. An amorphous nickel phosphorous (Ni—P) underlayer is formed over each surface of the disk substrate, typically by plating and is subsequently polished and sometimes texturized prior to deposition of the additional films. The Ni—P layer is hard, and imparts rigidity to the aluminum substrate. Alternatively, glass and other non-metallic materials are now used to form highly rigid disk substrates. A second underlayer in the form of a chromium ground layer is formed over the Ni—P layer, typically by sputtering, and a magnetic layer is formed over the ground layer. The magnetic layer comprises a thin film of ferromagnetic material, such as a magnetic oxide or magnetic metal alloy. Usually, a protective layer, such as a carbon film, is formed over the magnetic layer and a lubricating layer is formed over the protective layer. 
         [0003]    The presence of the Ni—P underlayer, together with the chromium ground layer, has been found to improve the recording characteristics of the magnetic layer. In particular, the chromium ground layer formed over a Ni—P layer provides enhanced coercivity and reduced noise characteristics. Such improvements are sometimes further enhanced when the Ni—P underlayer is treated by mechanical texturing to create a roughened surface prior to formation of the chromium ground layer. The texturing may be circumferential or crosswise, with the preferred geometry depending on the particular composition of the cobalt-containing magnetic layer. 
         [0004]    The outer carbon protective layer serves a very different purpose. This protective layer has been found to greatly extend the life of magnetic recording media by reducing disk wear. Carbon has been shown to provide a high degree of wear protection when a thin lubrication layer is subsequently, applied. 
         [0005]    Such magnetic recording disk constructions have been very successful and allow for high recording densities. As with all successes, however, it is presently desired to provide magnetic recording disks having even higher recording densities. One method for increasing the areal density on rigid magnetic disks involves patterning the surface of a thin film disk to form discrete data tracks. Such “discrete track media” typically include surface geometry data which are utilized by the hard disk drive servo mechanism, allowing specific recording tracks to be identified, and providing feedback to improve the accuracy of read/write head tracking. 
         [0006]    The production of discrete track media and other magnetic recording media having patterned surfaces were described by S. E. Lambert et al. in Beyond Discrete Tracks: Other Aspects of Patterned Media, JOURNAL OF APPLIED PHYSICS, Vol. 69, 8:4724-26, Apr. 15, 1991. Each of the patterned media described were produced by sputter etching or ion milling a magnetic recording layer through a resist mask. The resist mask was written with an electron beam, as is known in the lithographic arts. 
         [0007]    The production of discrete track media with a pre-embossed rigid magnetic disk was described by D. Dericotte, et al., in Advancements in the Development of Plastic Hard Disks With Pre-embossed Servo Patterns, CORPORATE RESEARCH LABORATORIES, SONY CORPORATION. The disk is produced using an injection molding process between two stamping plates. The plates containing the media surface pattern are produced using lithographical techniques. 
         [0008]    Recording media having a selectively laser-textured surface and methods for their production are described in U.S. Pat. Nos. 5,062,021, and 5,108,781, respectively. A laser system for texturing a substrate, Ni—P layer, or a magnetic recording layer is also disclosed. 
         [0009]    Discrete track media, however, suffer from their own disadvantages. The surface patterns of discrete track media have generally been imposed using standard lithographic techniques to remove material from the magnetic recording layer or by creating recessed zones or valleys in the substrate prior to deposition of the magnetic material. In the former case, the magnetic recording material is etched or ion milled through a resist mask to leave a system of valleys which are void of magnetic material. In the latter case, the magnetic film, subsequently applied, is spaced far enough away from the recording head that the flux from the head does not sufficiently “write” the magnetic medium. Servo track information can be conveyed by the difference in magnetic flux at the boundary between the elevated patterns and the valleys. However, the boundary signals have at most 50% of the amplitude of conventionally recorded data. Additionally, fabrication of production quantities of discrete track media has remained problematic, due in part to the expense of the required lithographic processes. 
         [0010]    A narrower track width corresponds to a higher areal density. The photo patterning of media helps separate tracks and also helps increase the areal density. However, the track width produced by photo patterning is greatly limited and does not achieve the desired narrow widths. 
         [0011]    There is ever growing need for high areal densities. Sensor dimensions are reduced to read and writer small dimension tracks. In addition to the sensor, the magnetic media also plays a key role in enhancing areal densities. For these reasons, it would be desirable to provide an improved method for producing a discrete track patterned media. It would be particularly desirable if such a method provided the accuracy and reproducibility of lithography, but did not involve multiple process steps or the complex, dedicated tooling required for stamping. It would be best if such a method enhanced the improvements to the magnetic recording characteristics available using the conventional underlayers, magnetic recording layers, and overlayers of high density magnetic recording media. 
       SUMMARY 
       [0012]    The present invention is related to a method of fabricating a media for magnetic recording media. A base layer is provided onto which a magnetic film is deposited from a first magnetic sputtering target. A non-magnetic film is then deposited on top of the base-layer from a second sputtering target. The magnetic layer and non-magnetic layer are repeatedly deposited a predetermined number of times to produce a media source. 
         [0013]    In a further aspect of the present invention, the base layer comprises a cylindrical rod, such that the alternating magnetic and non-magnetic layers form radially around the rod. If the layers are deposited simultaneously, the layers can form a spiral extending outwardly from the center of the rod. Alternatively, the layers can form concentric circles around the rod. 
         [0014]    In yet a further aspect of the present invention, if the base layer is a rod, the resulting media layers can be sliced to form recording media discs. Alternatively, the rod can be used to stamp the discrete pattern onto other discs. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0015]    The foregoing and other features of the present invention will be more readily apparent from the following detailed description and drawings of the illustrative embodiments of the invention wherein like reference numbers refer to similar elements throughout the views and in which: 
           [0016]      FIG. 1  illustrates a top view of a disk made in accordance with an embodiment of the present invention; 
           [0017]      FIG. 2  illustrates the process by which a disk is made in accordance with an embodiment of the present invention; 
           [0018]      FIG. 3  illustrates a media rod during the formation process made in accordance with an embodiment of the present invention; 
           [0019]      FIG. 4  illustrates a process by which the media rod is converted into disks in accordance with an embodiment of the present invention; 
           [0020]      FIG. 5  illustrates a process by which the media rod is used to create disks in accordance with an embodiment of the present invention; 
           [0021]      FIG. 6  illustrates a process by which the media rod is used to create disks in accordance with another embodiment of the present invention; 
           [0022]      FIG. 7  illustrates a further media source in accordance with an embodiment of the present invention; and 
           [0023]      FIG. 8  illustrates a process by which a media source is made in accordance with an embodiment of the present invention. 
       
    
    
     DETAILED DESCRIPTION 
       [0024]    The present invention relates generally to magnetic recording media, and more particularly to magnetic media formed where the tracks are created by film deposition and width of each tracks is controlled by the film deposition parameters. 
         [0025]    By way of overview, the present invention provides a new media for which the track-width (i.e., KTPI) is defined by the thickness of a sputter deposition/plating film. Film thickness can be controlled down to few angstroms. Therefore, the tracks can be controlled and produced having dimensions of similar size. Furthermore, the grain size of tracks produced in accordance with this invention will be well defined and small since narrow tracks require deposition of thin films. Such media will also enable high linear density. Narrow tracks also provide well defined grains in the down track direction by depositing magnetic films in a texture of a granular matrix. The present invention can produce discreet track media using magnetic layers that have different anisotropy fields (“Hk”) and exchange, and can include non-magnetic layers (e.g., metal or insulators). 
         [0026]    With reference to  FIG. 1 , an exemplary disk  100  is illustrated. Disk  100  can include an open or hollow center  110  which is surrounded by multiple magnetic layers  120  and non-magnetic layers  130 . Preferably, the magnetic layer  120  has a track width  140  of about 2 nm. The magnetic layer can be made of materials known in the art for such purposes (e.g., CoPt). 
         [0027]    The non-magnetic film can be an insulator or metallic. Further, the process used to deposit the non-magnetic film can be aqueous, for example by plating with a nonmagnetic metallic layer. The non-magnetic layer  130  preferably has a width of 2 nm and is made of alumina. 
         [0028]      FIG. 2  illustrates a process  200  by which disk  100  can be created. A cylindrical rod  210  made of a suitable material can be rotated about its axis in direction  240 . Two deposition targets are placed perpendicular to the rotational axis. The first target  220  deposits a magnetic layer, such as CoPt, on the rod  210  as it rotates about axis  240 . The second target  230  deposits an insulating, non-magnetic layer, such as alumina, on the rod  210 . The deposit parameters are preferable adjusted such that each target deposits a thin layer (e.g., 2 nm) of film on the rod  210  in a single revolution of the rod  210 . The films that result from this configuration spiral outwardly from the rod  210 . However, if repeating concentric layers of film are preferred, shutters can be used to control the exposure of the rod  210  to each target  220  and  230  such that only one of the targets is exposed during a single rotation of the rod  210 . As the cylinder increases in diameter, the parameters of the deposition system can be adjusted to ensure that the thickness of the magnetic and/or non-magnetic layers is the same for each deposition layer. 
         [0029]    Further, if it is desired that the center of the disk remain hollow, a material that can be etched selectively (e.g., Cu) can be used for the rod  210 . Applying a magnetic field along the axis of the rod  210  can result in perpendicular anisotropy of the film layers deposited on the rod  210 . 
         [0030]    Once the rod  210  completely a predetermined number of rotations, a layered structure “Media Rod”  310  is produced by the depositions of magnetic layer(s) from target  320  and depositions of non-magnetic layer(s) from target  330 , as illustrated in  FIG. 3 . The media rod  310  has concentric (or spiral) layers of magnetic media separated by non-magnetic spacers. The top (or bottom) surface  340  of the media rod  310  exposes the concentric layers of deposited film. 
         [0031]    Once the media rod is produced, it can be used to create individual media disks.  FIG. 4  illustrates one use of the media rod  410  to create media disks  430 . The media rod  410  can be cut (i.e., sliced)  420  into multiple individual disks  430 . The central Copper (Cu) can be etched into the disks  430  selectively, if necessary. The thickness of the magnetic film defines track-width in this particular method. Optionally, the individual disks  430  can be placed on a support disk. Further, a highly permeable material can be deposited on the substrate of the disk  430  to create a soft underlayer (SUL). The final disk  430  can be polished to smooth its surface. 
         [0032]    Because a disk made by slicing the media rod  410  is thicker compare to deposited magnetic films (track-widths), the anisotropy direction is preferably perpendicular to disk surface. 
         [0033]    Alternatively, once the media rod  510  is produced, it can be used to imprint circular tracks on a disk. For example, as illustrated in  FIG. 5 , a disk  520 , preferably made of Silicon (“Si”) or an appropriate metal, can be heated to a predetermined temperature. The media rod  510  can then be used to stamp the heated disk  520  to imprint the concentric (or spiral) tracks on the media rod  510  onto the printed media disk  530 . 
         [0034]    In a further alternative, as illustrated in  FIG. 6 , the surface of the media rod  610  can be heated to a predetermined temperature such that when stamped onto a transfer disk  620 , the top surface of the media rod  620  is transferred to the printed media disk  630 . The media rod  620  can be heated with external agent (e.g., a laser) preferably to a temperature that liquefies the top surface. Optionally, the surface of the printed media disk  630  can be polished for smoothness. 
         [0035]    In accordance with yet a further aspect of the present invention, a cylindrical drive  720  can be produced from the alternating deposition of magnetic and non-magnetic films. As illustrated in  FIG. 7 , a media layer  710  is created by depositing alternating layers of magnetic and non-magnetic layers. Preferably media plates are sputter deposited to create alternating layers corresponding to the track width. Cylindrical disks can be punched or cut out of the media layer  710  to produce a cylindrical drive  720 . The thickness of the magnetic layer corresponds to the track-width and the non-magnetic thickness corresponds to the spacing between the tracks. 
         [0036]    The media layer  810  can be produced using process  800  illustrated in  FIG. 8 . A conveyor-belt  850 , or similar mechanism, can transport a media layer  810  through the manufacturing process. Multiple deposition targets are positioned relative to the conveyor belt such that a thin film will be deposited on the media layer  810  as it comes within proximity to the deposition target. 
         [0037]    For example, conveyor-belt  850  can oscillate media layer  810  back and forth such that deposition target  820  sputter deposits a magnetic layer, deposition target  830  sputter deposits a non-magnetic layer, and deposition target  840  sputter deposits another magnetic layer. The convey-belt can then reverse directions such that deposition target  830  deposits a further non-magnetic layer, and deposition target  820  deposits a further magnetic layer. This process can be repeated until the desired number of magnetic layers have been deposited on the media layer  810 . The media layer  810  can then be cut into cylinders as described above, thereby producing cylindrical storage devices. 
         [0038]    It is to be understood that even though numerous characteristics and advantages of various embodiments of the invention have been set forth in the foregoing description, together with details of the structure and function of various embodiments of the invention, this disclosure is illustrative only, and changes may be made in detail, especially in matters of structure and arrangement of parts within the principles of the present invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed. For example, the particular elements may vary depending on the particular application while maintaining substantially the same functionality without departing from the scope of the present invention. In addition, although the preferred embodiment described herein is directed to a magnetic data storage device, it will be appreciated by those skilled in the art that the teachings of the present invention can be applied to optical devices without departing from the scope of the present invention. The implementations described above and other implementations are within the scope of the following claims.