Light delivery technique for heat assisted magnetic recording head

A suspension arm for an optical transducer comprises a load beam, a slider coupled to the load beam by a gimbal assembly and including an optical transducer positioned adjacent to an end of the slider facing a pivot point of the suspension arm, and an optical fiber for transmitting light toward the transducer, wherein an end of the optical fiber is positioned adjacent to the transducer such that light emitted from the fiber passes directly to the transducer. Disc drives that include the suspension arm, and a method of transmitting light to an optical transducer, are also included.

FIELD OF THE INVENTION

This invention relates to data storage devices, and more particularly to such devices that can be used in optical recording and thermally assisted magnetic recording.

BACKGROUND OF THE INVENTION

In thermally assisted optical/magnetic data storage, information bits are recorded on a layer of a storage medium at elevated temperatures, and the heated area in the storage medium determines the data bit dimension. Heat assisted magnetic recording (HAMR) generally refers to the concept of locally heating a recording medium to reduce the coercivity of the recording medium so that the applied magnetic writing field can more easily direct the magnetization of the recording medium during the temporary magnetic softening of the recording medium caused by the heat source. For heat assisted magnetic recording (HAMR) a tightly confined, high power laser light spot is used to preheat a portion of the recording medium to substantially reduce the coercivity of the heated portion. Then the heated portion is subjected to a magnetic field that sets the direction of magnetization of the heated portion. In this manner the coercivity of the medium at ambient temperature can be much higher than the coercivity during recording, thereby enabling stability of the recorded bits at much higher storage densities and with much smaller bit cells. Heat assisted magnetic recording can be applied to any type of magnetic storage media, including tilted media, longitudinal media, perpendicular media and patterned media.

In HAMR disc drives, it is desirable to efficiently deliver the laser light to the recording head. One approach would be to place a laser source directly on the slider. However, that approach requires additional electrical connections to the slider for the laser. Also, the electrical power dissipated by the laser will substantially heat the slider, which is undesirable for obtaining the best performance from the reader. The added mass of the laser on the slider (or suspension assembly) may also degrade the dynamic and shock performance of the suspension.

Alternatively, a laser source can be located elsewhere in the disc drive and its emitted light carried to the slider through an optical fiber. This approach eliminates the problems with the laser on the slider mentioned above, but introduces a new problem, which is how the optical connection is made between the fiber and the slider. Optical fiber is typically very stiff. If the fiber is physically attached to the slider, the stiffness complicates the design of the gimbal structure which allows the slider to fly over the surface of the disc. Therefore, it is desirable to have a small free space gap between the end of the fiber and the slider. The fiber should be brought to the slider along the suspension and then positioned so that the emitted light illuminates the optical transducer on the slider. One way that has been proposed to do this is to include a mirror or prism on the suspension to direct the laser beam toward the slider.

There is a need for a recording device that can provide localized heating of a recording medium without the need for mirrors, multiple optical components or sharp bends in an optical fiber.

SUMMARY OF THE INVENTION

This invention provides a suspension arm for an optical transducer comprising a load beam; a slider coupled to the load beam by a gimbal assembly and including an optical transducer positioned adjacent to an end of the slider facing a pivot point of the suspension arm; and an optical fiber for transmitting light toward the transducer, wherein an end of the optical fiber is positioned adjacent to the transducer such that light emitted from the fiber passes directly to the transducer.

In another aspect, the invention provides a disc drive comprising a motor for rotating a storage medium; and a suspension arm for positioning an optical transducer adjacent to a surface of the storage medium, wherein the suspension arm includes a load beam, a slider coupled to the load beam by a gimbal assembly and including an optical transducer positioned adjacent to an end of the slider facing a pivot point of the suspension arm, and an optical fiber for transmitting light toward the transducer, wherein an end of the optical fiber is positioned adjacent to the transducer such that light emitted from the fiber passes directly to the transducer.

The invention also encompasses a disc drive consisting essentially of a motor for rotating a storage medium, and a suspension arm for positioning an optical transducer adjacent to a surface of the storage medium, wherein the suspension arm includes a load beam, a slider coupled to the load beam by a gimbal assembly and including an optical transducer, and an optical fiber for transmitting light directly toward the transducer.

The invention further encompasses a suspension arm for an optical transducer consisting essentially of a load beam, a slider coupled to the load beam by a gimbal assembly and including an optical transducer, and an optical fiber for transmitting light directly toward the transducer.

The invention also encompasses a method of transmitting light to an optical transducer, the method comprising: coupling a slider to a load beam by a gimbal assembly, wherein the slider includes an optical transducer positioned adjacent to an end of the slider facing a pivot point of a suspension arm; and transmitting light toward the transducer using an optical fiber, wherein an end of the optical fiber is positioned adjacent to the transducer such that light emitted from the fiber passes directly to the transducer.

DETAILED DESCRIPTION OF THE INVENTION

This invention encompasses various devices used for heat assisted magnetic recording.FIG. 1is a pictorial representation of a disc drive10including a suspension arm constructed in accordance with this invention. The disc drive includes a housing12(with the upper portion removed and the lower portion visible in this view) sized and configured to contain the various components of the disc drive. The disc drive includes a spindle motor14for rotating at least one data storage medium16within the housing, in this case a magnetic disc. At least one arm18is contained within the housing12, with each arm18having a first end20with a recording and/or reading head or slider22, and a second end24pivotally mounted on a shaft by a bearing26. An actuator motor28is located at the arm's second end24, for pivoting the arm18about a pivot point to position the head22over a desired sector of the disc16. The actuator motor28is regulated by a controller that is not shown in this view and is well-known in the art. The storage medium rotates in the direction indicated by arrow30. As the disc rotates, the slider flies over the disc surface on an air bearing. The slider is positioned at the upstream end of the arm.

For heat assisted magnetic recording (HAMR), an electromagnetic wave of, for example, visible, infrared or ultraviolet light is directed onto a surface of a data storage medium to raise the temperature of a localized area of the medium to facilitate switching of the magnetization of the area. Recent designs of HAMR recording heads include a thin film waveguide on a slider to guide light to the storage medium for localized heating of the storage medium. To launch light into the waveguide, a grating coupler can be used.

FIG. 2is a schematic representation of a portion of a suspension arm32and slider34as is known in the art, in combination with a magnetic recording disc36. During writing and/or reading of data, the disc moves relative to the slider in a direction indicated by arrow38. The slider is coupled to the suspension arm by a gimbal assembly40positioned adjacent to a surface42of the disc and separated from the surface of the disc by an air bearing44. The gimbal assembly includes a first portion41connected to the suspension arm32and a second portion42connected to the slider34. The second portion is cantilevered to the first portion. The slider has a leading, or front, end46and a trailing, or back, end48. The leading end faces toward the pivot point of the suspension arm and the trailing end faces away from the pivot point of the suspension arm. The slider includes an optical transducer50mounted adjacent to the trailing end. A laser produces a beam of light illustrated by arrow52that is transmitted toward the slider by an optical fiber54. A mirror56is mounted at the end of the suspension arm to reflect the light toward the optical transducer. The fiber is attached to the suspension arm and terminates before the end of the suspension. The prism or mirror directs the output from the fiber onto the transducer on the slider. Additional lenses are almost certainly necessary to maintain a small beam diameter. The disadvantages of this technique include the additional expense of the prisms, lenses and mirrors, additional mass and windage, and the difficulty of aligning the microoptics and maintaining alignment as the slider flies on the disc and moves slightly relative to the suspension.

FIG. 3is a schematic representation of a portion of a suspension arm62and slider64constructed in accordance with this invention, in combination with a magnetic recording disc66. During writing and/or reading of data, the disc moves relative to the slider in a direction indicated by arrow68. The slider is positioned adjacent to a surface70of the disc and separated from the surface of the disc by an air bearing72. The slider has a leading end74, also called a front or distal end, and a trailing end76, also called a back or proximal end. The leading end faces away from, and is therefore distal to, the pivot point of the suspension arm and the trailing end faces toward, and is therefore proximal to, the pivot point of the suspension arm. The slider includes an optical transducer78mounted adjacent to the trailing end. A source of electromagnetic radiation, such as a laser80, produces a beam of light illustrated by arrow82that is delivered to the optical transducer78by an optical fiber84. The optical fiber84is supported by block90that is mounted on the suspension arm. The optical transducer can include a grating coupler86for coupling the light into the transducer. The optical transducer can further include a planar waveguide92for transmitting light to the air bearing surface of the slider. The light is then coupled to the surface of the disc to raise the temperature of a portion of the surface of the disc. The slider further includes a magnetic recording head88for producing a magnetic field that is used to affect the magnetization of the storage medium. A read head can also be included.

The slider is connected to the suspension arm62by a gimbal assembly94. The gimbal assembly includes a first portion96connected to the suspension arm62and a second portion98connected to the slider64. The second portion is cantilevered to the first portion. The gimbal assembly ofFIG. 3is reversed when compared to the gimbal assembly ofFIG. 2. However, in another example, the gimbal assembly94ofFIG. 3could be replaced with the gimbal assembly40ofFIG. 2.

The optical transducer can include a planar waveguide including a core layer for transmitting electromagnetic radiation and a cladding layer positioned adjacent to the core layer.

FIG. 4is a schematic representation of a slider100constructed in accordance with this invention. An optical transducer102is positioned adjacent to the trailing end (back or proximal)104of the slider. The transducer includes a guiding core layer106and a grating coupler108. An optical fiber110, having a ball lens112is positioned to deliver light to the transducer as indicated by arrow114. The angle of incidence of the light is defined as θ measured from the normal to the surface of the slider.

FIG. 5is a graph of the grating period versus angle of incidence for optimal coupling into the waveguide. The optical fiber with a lens at the tip can emit a collimated beam toward the trailing edge of the slider where the transducer is located. For example, Corning Optifocus™ fibers can emit collimated beams with typical diameters of 62 μm. To receive light from the optical fiber, the transducer on the slider can also be designed to have a diffraction grating etched into the top end of the waveguide. If the period and depth of the grating are properly chosen, then a collimated beam incident upon the grating at the angle shown inFIG. 5will be efficiently coupled into the waveguide. For example, for a waveguide comprised of a 100 nm Ta2O5core on top of an SiO2cladding layer with air on the outside of the core, and light with a wavelength of 633 nm and TE polarization, the angle of incidence as a function of grating period is shown inFIG. 5.

FIG. 6is a graph of the reflectance versus angle of incidence for the grating coupler. If the angle of incidence onto the grating is 10°, then for the previous example waveguide, a grating with a period of 432 nm is needed to excite the lowest order TE waveguide mode.FIG. 6shows the calculated reflectance of a 50 nm deep grating in this waveguide.FIG. 6shows the effect of the resonant coupling of light into the waveguide at the desired angle. Thus for effective light delivery to the disc, the fiber needs to be in good alignment with the slider.

FIG. 7is an isometric view of the bottom side of a suspension arm120and slider122constructed in accordance with this invention. The suspension arm includes a load beam124that supports a flex circuit126and the slider. The flex circuit126includes a first sheet128of, for example polyimide material, that supports conductors130and132, and a second sheet134of, for example polyimide material, that supports conductors136and138. The conductors130,132,136and138can be mounted on the surface of the sheets128and134. An optical fiber140is positioned between the flex circuit sheets, and is supported by the suspension arm. An alignment block142is provided near the end of the optical fiber to properly position the end of the fiber so that it directs light onto the optical transducer at the correct angle. The alignment block is connected to the load beam124and can include a groove for accepting the optical fiber to prevent lateral movement of the fiber. A gimbal assembly144couples the slider to the load beam.

A load/unload tab146is provided at the end of the arm. The load/unload tab can be used in combination with other well-known structures such as a load/unload ramp to prevent contact of the slider with the disc when the disc is stopped. If the slider were allowed to contact the disc during startup, the suspension arm would be subject to buckling forces due to friction effects caused by reverse spinning of the disc. By including a load/unload tab, the buckling forces are avoided. If the load/unload tab is not used, the arm can be made strong enough to withstand the buckling forces.

One possible assembly for mounting the optical fiber includes alignment tabs (or indentations) on the suspension with the fiber being glued directly along these tabs. Another assembly, as illustrated inFIG. 7, attaches the fiber to a small block that is subsequently glued onto the suspension. The use of a mounting block complies well with existing head gimbal assembly (HGA) procedures since a deep or sloped indentation is not required to be created on the suspension.

FIG. 8is an end view of the alignment block142showing the optical fiber140in a groove148. The optical fiber can be secured in the groove by glue and the alignment block can be attached to the suspension arm using glue or other attachment means. The alignment block is connected directly to the load beam and the flex on suspension (FOS) is split into left and right sections that are positioned on opposite sides of the fiber. Alignment fiducials can be provided to align the fiber block unit with the suspension load beam.

An alignment aid such as a V-groove can be used to attach the fiber precisely to the block. The block thickness can be chosen to provide the needed angle of incidence of the light onto the optical grating on the slider. Precision mounting of the fiber mounting block unit can be achieved using optical component manufacturing technology and would not complicate suspension fabrication or the gimbal assembly process.

FIG. 9shows an alternative means for supporting the optical fiber near its end by using a tab150extending from the suspension arm. The tab can also include a groove152for accepting the optical fiber140.

In alternative structures, the optical fiber can be mounted on the flex circuit sheet or embedded therein. The sheet material can be partially etched along the load beam to create an alignment groove (indentation) to which the fiber block can be attached. Such grooves are compatible with typical suspension fabrication process.

FIG. 10is a top view of a slider122and a portion of a flex circuit126. The flex circuit includes sheets128and134that support conductors130,132,136and138. An optical fiber140is positioned along the center of the flex circuit and supported near one end by a mounting block142. Connection points154are provided to connect the conductors to the magnetic recording head mounted on the slider, in accordance with known techniques. The examples described above provide a basic approach to deliver light to a slider through an optical fiber by reversing the orientation of the slider by 180 degrees. Through the use of an alignment block (with precise alignment to the fiber) and/or an alignment groove or other alignment structure on the suspension, precise position and angular alignment (to a very small fraction of a degree) can be established between the fiber and the suspension load beam (to which the fiber alignment block is attached).

However, precise alignment between the fiber and the suspension load beam does not guarantee alignment between the fiber and the optical grating on the slider. In particular, the pitch angular tolerance of the load beam with respect to the slider or the recording disc can be ±1 degree due to a number of manufacturing tolerance limits such as suspension pre-load bending, head-stack assembly, and the media and spindle assembly. For example, variation in the height of the suspension base plate with respect to the recording disc (the z-height) will cause the suspension to bend, resulting a different load beam angle, and thus a different fiber angle.

Furthermore, this misalignment cannot be accounted for prior to the drive assembly process. Unless tolerances of all the drive subcomponents are substantially reduced, additional design features or angular adjustment of the fiber during the drive assembly process are needed in order to achieve the final angular tolerance between the fiber and the slider grating (±0.1 deg).

While the alignment block of the fiber as described above will point the fiber without stress toward the slider grating with some finite accuracy, further accuracy can be achieved by attaching the tip of the fiber to the end section of the FOS which is bonded directly to the slider bond pads.FIG. 11is a top view of a slider160and a portion of a flex on suspension162wherein the optical fiber164is mounted on a block166that is connected to an end of the FOS. The FOS includes a sheet of material that supports conductors168,170,172and174. Connection pads176are used to connect the conductors to the recording head. The end section of the FOS will naturally be rigid and aligned with the slider. Thus the fiber will be aligned with similar accuracy. Alternatively, the tip of the fiber (with the ball lens) can simply be glued to the FOS or potentially the fiber can be integrated into the FOS to eliminate this assembly step (and the use of the alignment block). This approach could eliminate the need for pitch angle adjustment during drive assembly and provides a manufacturable solution.

Other examples provide for aligning the tip of the fiber to the top surface of the recording disc. The top surface of the recording disc has a well-defined angular relationship with the optical grating on the trailing edge of the slider (as governed by the flying dynamics of the air bearing). Therefore, to align the fiber to the grating of the recording slider, the tip of the fiber can be attached to a reference object, which is also flying on the surface of the disc.

FIG. 12is a schematic representation of another slider and a portion of a suspension arm constructed in accordance with this invention. Many of the components ofFIG. 12are the same as the components ofFIG. 3and carry like reference numbers. In the example ofFIG. 12, the reference object takes the form of a reference slider180that is connected to a separate suspension arm182and connected to the optical fiber84by a block184, or a suitable gimbal structure.

This reference object may be a simple plate or bar structure attached to the tip of the rotary actuator assembly driven by the voice-coil magnet so that the actuator, the reference object, and the slider (which is connected to the actuator through the suspension) will all move in synchrony. Unlike the slider, which requires a precise fly height and cross-track position, this reference object can have large tolerances as long as its relative position to the slider is within the tolerance of the fiber with respect to the optical grating.

This configuration enables the fiber to stay pointed towards the slider regardless of many assembly variations, since the fiber is now aligned to the slider via the top surface of the recording disc through the flying reference object. No pitch angle adjustment would be needed. Furthermore, in this case the fiber is connected to the reference object and is not directly connected to the slider. Therefore, the fiber doesn't directly impact the slider's dynamic performance.

Another approach for aligning the fiber uses an angular adjustment via metal deformation through laser heating.FIG. 13is a schematic representation of a slider and a portion of an optical fiber constructed in accordance with this approach. Many of the components ofFIG. 13are the same as the components ofFIG. 3and carry like reference numbers.FIG. 14is an enlarged view of the structure for supporting an optical fiber in the example ofFIG. 13. The mounting block92is connected to another block190that is connected to the arm62by one or more welds194. A laser196can be used to produce the welds. The welds deform the mounting structure so that the position of the end of the optical fiber can be moved as illustrated by arrow198. The number, size, and position of the welds can be controlled to adjust the position of the end of the optical fiber.

The aggregate angular misalignment cannot be precisely known until the slider is loaded on the recording disc. The magnitude of the offset or the direction of improvement can be estimated or determined by applying light to the grating through the fiber and observing the reflected light from the media. Therefore, fine angular correction of the optical coupling between the optical fiber and the grating can be achieved through iterations of slider head gimbal assembly (HGA) load, optical feedback through the fiber, HGA unload, and adjustment of the position of the optical fiber end. Thus the alignment of the optical fiber and the optical transducer can be adjusted in response to light reflected from a storage medium.

The angular adjustment must not require the disassembly of the HGA drive assembly since each new assembly may introduce new offsets, effectively voiding the most recently adjustment. Therefore, the adjustment must be done at the drive level. While the misalignment “error” signal is available only when the HGA is loaded and the slider is flying, it is best to perform the adjustment when the HGA is unloaded, and preferably parked to the side. In this case, the adjustment process will not impose any risk of slider head crashing. Away from the media, the HGA also becomes more accessible.

The use of robot arms can theoretically accomplish the task. Robotic tweezers can apply a small twist and bend to the fiber alignment block to modify its relative angle with respect to the slider. In practice, this approach is not feasible without the expensive development of precision micro-robotic arms. Furthermore, this approach is likely limited to single-disc single-arm drives.

The angle adjustment can be accomplished by applying heat to the joints, flexures, or block which may be supporting the fiber that is roughly aligned to the grating. Through the application of heat, the joints, flexures, or block deforms or misaligns slightly, leading to an increasing optical coupling power between the optical fiber and grating. This heating process must generate negligible particles in order to preserve the cleanliness of the head-to-media interface. Heat ideally should be applied only to small regions in order to avoid undesirable thermal effects in the drive.

Heat can be applied through a laser beam. Through the iterative process described earlier, adding welding spots between the fiber alignment block and the load beam to which the alignment block is attached can modify the angle of the fiber. The fiber may be initially biased so that by adding welding spots the fiber monotonically moves toward the ideal position. Alternatively, a mechanical support which can be plastically deformed through heat can be used to position the end of the fiber. The support can be made of two (or multiple beams) acting in tension. Using heat, it is possible to deform the shape or alter the stiffness of one beam, thus changing the angle of the fiber.

Another approach to angular adjustment of the optical fiber tip uses metal deformation through electrical current heating.FIG. 15is a mounting structure200that can be used to mount an optical fiber202to the arm. The mounting structure includes a frame204that includes two deformable struts206and208. An electric current can be passed through the struts, thereby heating and deforming the struts and moving the tip of the optical fiber as illustrated by arrow210.

Similar to the approach described above, heat is used for deformation. However, in this case, the heat is generated by applying a current to the head gimbal assembly (HGA). This current could theoretically be applied through the FOS. But extra wires on the FOS may compromise the dynamic response of the HGA, especially since advanced read-writer heads already require the traditional four or five wires on a FOS.

To avoid the need for additional wires on the FOS, the current can be applied through contact leads on the side of the drive. To access these contacts, the actuator motor moves the suspension arm to a position past the docking position of the arm.FIG. 16is a pictorial representation of a magnetic disc drive that can include a suspension arm constructed in accordance with this invention. Contacts220and222are mounted on a block224near the side of the disc drive. The slider is capable of being positioned in a storage position226or in an adjustment position228. In the adjustment position, the contacts supply current to the mounting structure. The current can be used to heat and deform the mounting structure to adjust the position of the tip of the optical fiber. Then the arm is returned to a position over the disc for further calibration.

The HGA may be made of multiple layers, some of which are electrically insulated. This is possible using current trace suspension assembly (TSA) technology. The applied current can generate heat in a region through a high resistance current path. The heat may either deform the current layer or another adjacent layer, plastically unbalancing the mechanical stress of the structure supporting the fiber as described earlier, thus adjusting the fiber angle.

With this approach, no special mechanism is needed for angle adjustment in the drive assembly process because the drive actuation motor is used. Minimal hardware modification inside the drive is required except for adding two electrical contact points beyond the normal docking position of the suspension arm. However, no hole or special access points must be created. Most importantly, the approach is suitable for not only single-disc single-head drives but also for multi-disc multi-head drives.

This invention simplifies the optical path in an optical or magneto-optical disc drive by reversing the direction of disc rotation and mounting an optical fiber on the suspension arm. No bending of the fiber is needed. The fiber can be designed to have a lens on its tip so that it emits a collimated beam at the edge of the slider where the transducer is located. The fiber can be mounted along the center of the suspension load beam to ensure that there is no asymmetrical stiffness contribution to the suspension and gimbal modes.

To implement the reversed slider-direction approach, the disc would need to spin in the opposite direction compared to a typical disc drive, since typical sliders have transducers which are located at the trailing edge of the air bearing. During startup when the slider is in contact with the disc, this can subject the suspension to compressive forces. At the stationary flat position of the slider, the frictional forces between the slider and disc could cause the gimbal to buckle under compressive start-up forces due to friction. This can be overcome by designing the gimbal to withstand these forces. To avoid compressive forces on the suspension at start-up, the suspension could be a load-unload type where the slider is unloaded from the disc onto a ramp and so does not land on the disc.

For the slider orientation shown in the examples, it is most convenient to route the flex circuit under the load beam. Typical bonding technology may be used to attach the flex on suspension (FOS) to the bond pads on the trailing edge of the slider. To maximize the area for the optical grating, the bond pads would ideally be located at the topside of the slider. In that case, the slider must be mounted such that the bond pads are exposed for flex connection. In addition, the glue thickness on the gimbal tongue can be controlled so that the slider is attached at a slightly lower plane compared to the plane of the flex on suspension.

While the examples described above relate to heat assisted magnetic recording, wherein a transducer is used to heat a portion of the storage medium and the heated portion of the storage medium is subjected to a magnetic field to affect the magnetization of a storage layer in the storage medium, this invention can be used in other systems. For example, the invention can be applied to optical recording systems, or any other systems wherein an optical transducer is mounted on an arm. The invention can also be used in optical lithography systems or in other systems that perform optical operations such as scribing or cutting.

While the invention has been described in terms of several examples, it will be apparent to those skilled in the art that various changes can be made to the disclosed examples, without departing from the scope of the invention as set forth in the following claims.