Abstract:
A write element for a magnetoresistive (“MR”) head or a giant magnetoresistive (GMR) head includes a yoke and a coil. The coil made of a microstrip transmission line. The coil is a single turn and is U-shaped. The yoke of the write element includes laminated bottom pole, and top pole which are made of thin layers of ferromagnetic material antiferromagnetically exchange coupled to each other through a very thin nonmagnetic metallic layer. The yoke is made of metallic superlattices exhibiting strong antiferromagnetic exchange coupling between ferromagnetic layers through thin nonmagnetic metallic layers. The coil and the yoke are intertwined to provide two or more flux interactions between them. The yoke has a symmetrical structure with three interconnect vias, thereby reducing the effective magnetic length of the yoke. The antiferromagnetically exchange-coupled yoke has a stable single domain structure that exhibits very high switching time and does not suffer from hysteresis losses.

Description:
RELATED APPLICATION 
     This application claims the benefit of U.S. Provisional Application Ser. No. 60/230,400 entitled “HIGH-EFFICIENCY SINGLE-TURN WRITE HEAD FOR HIGH-SPEED RECORDING”, filed Sep. 6, 2000 under 35 U.S.C. 119(e). 
    
    
     FIELD OF THE INVENTION 
     This application relates generally to the field of electronic data storage and retrieval. More particularly, this invention relates to a transducer which includes a write element having a single-turn for high-speed magnetic recording with high efficiency. 
     BACKGROUND OF THE INVENTION 
     One of the key components of any computer system is a place to store data. One common place for storing data in a computer system is on a disc drive. The most basic parts of a disc drive are a disc that is rotated, an actuator that moves a transducer to various locations over the disc, and electrical circuitry that is used to write and read data to and from the disc. The disc drive also includes circuitry for encoding data so that it can be successfully retrieved and written to the disc surface. A microprocessor controls many of the operations of the disc drive including control of a data channel which passes data between a computer and the disc drive. Disc drive manufacturers are constantly increasing the amount of data that can be stored on the discs of a disc drive. The number of tracks per inch, the data density of bits or individual transitions within a track, as well as the rotational speed of the disc have all been increased over the years to increase the data capacity of disc drives. Increasing the data density within the track and the rotational speed of the disc have necessitated improvements in the speed or data rate of the data channel. In order to further increase the data capacity of disc drives, the transducer must be able to write and read data at increased data rates. In other words, the transducer will have to be able to write transitions to the disc at an increased rate and will have to be able to read transitions from the disc at an increased rate. 
     One type of transducer used in current disc drives is a giant magnetoresistive (“GMR”) read/write head. 
     A GMR read/write head generally consists of two portions, a writer portion for storing magnetically-encoded information on a magnetic disc and a reader portion for retrieving magnetically-encoded information from the disc. The reader portion typically consists of a bottom shield, a top shield, and a giant magnetoresistive (GMR) sensor positioned between the bottom and top shields. Magnetic flux from the surface of the disc causes rotation of the magnetization vector of a free layer of the GMR sensor, which in turn causes a change in electrical resistivity of the GMR sensor. The change in resistivity of the GMR sensor can be detected by passing a current through the GMR sensor and measuring a voltage across the GMR sensor. External circuitry then coverts the voltage information into an appropriate format and manipulates that information as necessary. 
     The writer portion typically consists of a top and a bottom pole, which are separated from each other at an air bearing surface of the writer by a gap layer, and which are connected to each other at a region distal from the air bearing surface by a back gap closer or back via. Positioned between the top and bottom poles are one or more layers of conductive coils encapsulated by insulating layers. The writer portion and the reader portion are often arranged in a merged configuration in which a shared pole serves as both the top shield in the reader portion and the bottom pole in the writer portion. 
     To write data to the magnetic media, an electrical current is caused to flow through the conductive coils to thereby induce a magnetic field across the write gap between the top and bottom poles. By reversing the polarity of the current through the coils, the polarity of the data written to the magnetic media is also reversed. Because the top pole is generally the trailing pole of the top and bottom poles, the top pole is used to physically write the data to the magnetic media. Accordingly, it is the top pole that defines the track width of the written data. More specifically, the track width is defined by the width of the top pole at the air bearing surface. 
     The data rate is one of the main characteristics of current disk drives. The MR element or GMR element is a spin valve and has no inductance or reluctance. As a result, the MR or GMR element can read at very high frequencies. As a result, the read element is able to accommodate high data rates. The limiting portion of hardware is the write element. The data rate of drives depends considerably on recording head or write element parameters, such as inductance, core length, domain structure, and resonance frequency. The inductance of the write head is defined primarily by the number of coil turns. To support high-speed recording, the smallest possible number of turns is highly desirable. Hence a write element with a single-turn coil should have minimal inductance. However, the write field is proportional to the number of coil turns and the write current. Decreasing the number of turns will require an increase of the write current, which is quite difficult to provide due to preamplifier limitations. 
     Current write elements use a coil. Conventional coils have problems at high data rates or when operating at high frequency. When recording at high data rates, the electrical wavelength is comparable to the coil dimensions. The result is that the conventional coil conductor cannot be used due to extensive losses. 
     The switching time of the write element during recording depends on the length and the domain structure of the yoke. Multidomain structure assumes the presence of domain walls that have low mobility, resulting in an increase of the write element switching time. Moreover, the domain walls cause power losses in the yoke that are proportional to the coercivity of the yoke. 
     The ferromagnetic resonance in the yoke can limit the efficiency and frequency range of the write element. To suppress that effect, the frequency of the ferromagnetic resonance of the yoke needs to be increased. The frequency of the ferromagnetic resonance increases with the increase of the effective anisotropy field of the yoke or with the reduction of permeability of the yoke material. 
     Therefore, what is needed is a write element capable of supporting a high data rate. A low reluctance, low inductance coil is needed. In addition, the coil must be able to handle information changing at high frequency without excessive loss in transmission. In addition, there is a need for a yoke with an increased ferromagnetic resonance. None of the existing write elements satisfies the above-mentioned needs. 
     SUMMARY OF THE PROPOSED SOLUTION 
     The present invention relates to a merged giant magnetoresistance (GMR) head for high data rate, and particularly, to the writing part of the head, which is capable of recording at a very high speed. The write element has a laminated antiferromagnetically exchange-coupled yoke and single-turn coil made of a microstrip transmission line. The coil and the yoke are intertwined to provide two or more flux interactions between them. 
     The write element includes a symmetrical planar magnetic yoke and single-turn coil. The coil has a U-shape form and a microstrip transmission line structure. The coil with the microstrip structure is capable of transmitting electrical signals with minimal loss in gygohertz diapason. The yoke is formed into a figure eight shape (∞-shape) and wrapped around the single-turn coil twice. That doubles the effective number of turns without increasing coil resistance and results in a substantial increase of the magnetic field produced by the write head. The yoke has a symmetrical structure with three interconnect vias, thereby reducing the effective magnetic length of the yoke. The yoke is made of metallic superlattices exhibiting strong antiferromagnetic exchange coupling between ferromagnetic layers through thin nonmagnetic metallic layers. The antiferromagnetically exchange-coupled yoke has a stable single domain structure that exhibits very high switching time and does not suffer from hysteresis losses. 
     For a fuller understanding of the nature and advantages of the present solution, reference should be made to the following drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is an exploded view of a disc drive with a multiple disc stack. 
         FIG. 2  is a schematic view of the drive electronics of the disc drive. 
         FIG. 3  is a plan view of a single-turn write element according to the present invention. 
         FIG. 4  is a view of the pole portions on a first level according to the present invention. 
         FIG. 5  is a view of the pole portions on a second level according to the present invention. 
         FIG. 6  is a cross-sectional view along line  6 — 6  of the write element shown in  FIG. 3 . 
         FIG. 7  is a cross-sectional view along line  7 — 7  of the write element shown in  FIG. 3 . 
         FIG. 8  is a cross-sectional view along line  8 — 8  of the write element shown in  FIG. 3 . 
         FIG. 9  is a schematic side view of the yoke and single-turn coil of the write element showing the double yoke-coil interaction according to the present invention. 
         FIG. 10  is a cross-sectional view along line  6 — 6  of a front portion of the write element given in  FIG. 3  with single-layer magnetic studs. 
         FIG. 11  is a cross-sectional view along line  6 — 6  of another embodiment of a write element having laminated magnetic studs. 
     
    
    
     DETAILED DESCRIPTION 
     In the following detailed description of the preferred embodiments, reference is made to the accompanying drawings which form a part hereof, and in which are shown by way of illustration specific embodiments in which the invention may be practiced. It is to be understood that other embodiments may be utilized and structural changes may be made without departing from the scope of the present invention. 
     The invention described in this application is useful with all mechanical configurations of disc drives having either rotary or linear actuation. In addition, the invention is also useful in all types of devices which use magnetic write elements. For example, the invention described could also be used in tape drives where magnetic transitions are formed on magnetic tape. 
       FIG. 1  is a view of one type of device that uses a magnetic write element.  FIG. 1  is an exploded of a disc drive  100  having a rotary actuator. The disc drive  100  includes a housing or base  112 , and a cover  114 . The base  112  and cover  114  form a disc enclosure. Rotatably attached to the base  112  on an actuator shaft  118  is an actuator assembly  120 . The actuator assembly  120  includes a comb-like structure  122  having a plurality of arms  123 . Attached to the separate arms  123  on the comb  122 , are load beams or load springs  124 . Load beams or load springs are also referred to as suspensions. Attached at the end of each load spring  124  is a slider  126  which carries a magnetic transducer  150 . On the end of the actuator assembly  120  opposite the load springs  124  and the sliders  126  is a voice coil  128 . The actuator assembly  120  is used to place the transducing in transducing relation with respect to the disc  134  so that magnetic transitions representing data can be written to a track on the disc  134  or so that the magnetic transducer can read data from the disc  134 . It should be noted that this invention is applicable to sliders having more than one transducer. As will be discussed in more detail below, the transducer of the invention has a separate read element and write element. 
     Attached within the base  112  is a pair of magnets  130  and  131 . The pair of magnets  130  and  131 , and the voice coil  128  are the key components of a voice coil motor which applies a force to the actuator assembly  120  to rotate it about the actuator shaft  118 . Also mounted to the base  112  is a spindle motor. The spindle motor includes a rotating portion called the spindle hub  133 . In this particular disc drive, the spindle motor is within the hub. In  FIG. 1 , a number of discs  134  are attached to the spindle hub  133 . In other disc drives a single disc or a different number of discs may be attached to the hub. The invention described herein is equally applicable to such other disc drives. 
     As shown schematically in  FIG. 2 , the disc drive includes electronics packages. These electronics packages include a data channel  200  which is used to encode and place individual magnetic transitions representing data onto the disc  134 , and which is used to decode the individual magnetic transitions upon reading and reassemble these into data. The data channel includes a preamp  202 , a data channel chip  204  and an interface  210  to a main computer. The electronics also include servo control circuit  240  for determining the amount of current that needs to be used with the voice coil  128  keep the transducer  150  over a desired track or to move the transducer  150  from one track to another track on the disc  134 . Although the schematic shows these circuits off the disc drive  100 , these circuits are generally part of the disc drive. In many disc drives these circuits are found in one or more chips attached to a printed circuit which is in turn attached to the base  112  of the disc drive  100 . 
       FIG. 3  is a plan view of a single-turn write element  300  according to the present invention. The single-turn write element  300  includes a yoke  400  and a coil  310 . The write element  300  has a single-turn coil  310  made as a microstrip transmission line. The coil  310  consists of two conductive layers  311  and  313 , isolated from each other by insulating layer  312 . The coil  310  is substantially U-shaped. 
     The coil  310  is formed as a transmission line so that through put signal is maximized and the transmission is done without excessive losses. More particularly, the coil  310  is a microstrip transmission line that has a conductive circuit on top of a dielectric substrate with a ground plane below the substrate. The microstrip transmission line avails itself of low cost production in large volume and no connecters are required between the circuit elements, thereby reducing size and resulting in very low losses. The two conductive layers  311  and  313 , as well as the insulative layer  312  between the conductive layers  311  and  313 , are geometrically positioned to produce a frequency impedance match. The size of the conductor, the spacing of the conductors with respect to the ground plane, and the geometry of the ground plane all affect the conductance and inductance of the conductors. The insulators and the separator are also spaced so that their permicivity and permeability produces a matched impedance. The advantages of using a coil  310  formed as a microstrip transmission line or a transmission line is that the write element is capable of handling high frequency write current and therefore can write data at a very high data rate. 
     Turning now to  FIGS. 4 and 5 , the geometry of the yoke  400  will be discussed. The yoke  400  is comprised of four yoke portions  410 ,  420 ,  510 ,  520  of material in two planes.  FIG. 4  is a view of the two yoke portions  410 ,  420  on a first plane or first level.  FIG. 5  is a view of the two yoke portions  510 ,  520  on a second level or second plane. As can be seen, each of the yoke portions  410 ,  420 ,  510 ,  520  are symmetrical. The yoke portions on the first plane  410 ,  420  overlap the yoke portions  510 ,  520  on the second plane. The yoke portions  410 ,  420  of the on the first plane are interconnected with the yoke portions on the second plane to form a substantially figure 8-shaped magnetic flux path that wraps around the legs of the U-shaped coil  300 . The yoke portions  410 ,  420  on the first plane are situated behind the yoke portions  510 ,  520  in  FIG. 3 . The yoke portion  410  connects to yoke portion  520  via a first external magnetic stud  431  and a second magnetic external stud  433 . The yoke portion  420  connects to the yoke portion  510  by a central magnetic stud  432 . Another magnetic stud  440  connects the yoke portion  520  and the yoke portion  420  at one end of the flux path. At the other end of the flux path a small magnetic stud  450  is attached to yoke portion  410  and does not touch yoke portion  510 . A write gap  442  is formed. The 
       FIGS. 6 ,  7  and  8  are various cross sectional views of the write element  300  shown in  FIG. 3 . Now looking at  FIGS. 3 ,  6 ,  7 ,  8 , the magnetic yoke  310  of the write element  300  consists of a planar bottom pole  410 ,  510  and top pole  420 ,  520  with a nonmagnetic write gap  442  is formed at the air-bearing surface of the slider. The yoke is wrapped around the U-shaped single-turn coil  310  twice, thus doubling the effective number of turns. To provide double interaction between the coil  310  and the yoke  400 , the bottom pole  410 ,  510  and top pole  420 ,  520 , respectively, consist of forward or front yoke portions  510 ,  520  on one plane and rear yoke portions  410 ,  420  on a second plane. The yoke portions  410 ,  420  have a nonmagnetic gap  430  between the yoke portions  410 ,  420 . The yoke portions  510 ,  520  have a nonmagnetic gap  530  between the yoke portions  510 ,  520 . The front portion  410  of the bottom pole is connected to the rear portion  520  of the top pole  5  through external magnetic studs  431  and  433 . The front portion  510  of the top pole is connected to the rear portion  420  of the bottom pole through the central magnetic stud  432 . The cross-sectional area of the central magnetic stud  432  is at least twice as large as the cross-sectional area of the external stud  431  and  433 . As shown in  FIG. 8 , the coil  310  is isolated from the yoke  400  by insulating layer  800 . The write gap  442  and throat height are defined by magnetic extension  450  of the bottom pole. 
     Now looking at  FIGS. 3–8 , the flux path will be discussed. 
     The switching current in the coil  310  induces a magnetic flux flow within the yoke  400  of the write element  300 . The flux path is shown with the aid of arrows carrying reference numerals in  FIGS. 3 ,  6 ,  7  and  8 . And arrow  810  and an arrow  812  show the flux path flow from the write gap  442  through the yoke portion  510  and then passes through the center stud  432  and upward through the yoke portion  420 , as depicted by arrows  820 ,  821  and  822  in  FIGS. 7 ,  6  and  8 , respectively. The flux path then includes passing through the top stud  440 , as depicted by arrow  830 . The flux path, depicted by arrow  830 , then passes into the yoke portion  520  and splits or substantially splits into two different flux paths, as depicted by arrows  840  and  841 . The flux path substantially splits because the yoke element  520  is symmetrical and the whole entire yoke  400  is also symmetrical in shape. Therefore, it can be predicted with reasonable certainty that the flux path through yoke element  520  substantially splits and then passes through the external studs  431  and  433  to the yoke element  410 , as depicted by reference numerals  850  and  851 . The flux then passes through the yoke element  410 , as depicted by arrows  860  and to the small magnetic stud  450  that is positioned so that it does not touch yoke portion  510  to produce the write gap  442 . The magnetic flux then bridges the write gap or passes through the write gap  442  where the flux is then used to write transitions to the surface of the disk  134 . This essentially completes the loop and the flux path that results from the current changes in the coil  310 . 
       FIG. 9  is a schematic side view of the yoke and single-turn coil of the write element showing the double yoke-coil interaction according to the present invention. The yoke  400  intertwined with the single-turn coil  310  provides at least two flux interactions between the yoke  400  and the coil  310 . The multiple flux interactions significantly increase the inductive coupling between the yoke  400  and the coil  310 . Thus, compared with write elements that have only a single flux interaction, a given amount of flux conducted by the yoke  400  during reading induces a greater electrical signal in the coil  310 , and during writing an increased level of flux is generated in the yoke  400  in response to the write signal applied to the coil  310 . In general, the induced electrical signal (during reading) and the induced flux (during writing) are increased by a factor equal to the increased number of flux interactions. 
       FIG. 10  is a cross-sectional view along line  6 — 6  of a portion of the write element given in  FIG. 3  with single-layer magnetic studs. Yoke portions  410 ,  420 , and  510  are shown in  FIG. 10 . The yoke portion  520  is not shown in  FIG. 10 . The center stud  432  and the extension  450  are made of a single metal layer. In this embodiment, the external magnetic studs  431 ,  433  are also made of a single metal layer. The magnetic stud  440  which connects the yoke portion  520  and the yoke portion  420  at one end of the flux path, although not shown, would also be made of a single metal layer. Each of the yoke portions  410 ,  420 ,  510 ,  520  is formed as a laminated element. The laminated elements are made of a thin layer of ferromagnetic material  1011  and  1013  antiferromagnetically exchange coupled to each other through a very thin nonmagnetic metallic layer  1012 . The ferromagnetic layers  1011 ,  1013  have low coercivity, low magnetostriction and high magnetic moment and are 30–100 nm thick. The ferromagnetic layers  1011 ,  1013  are made of materials such as Ni45Fe55, NiFeCo, or FeCo. The thin nonmagnetic layers  1012  are made of Ru, Rh, Re, Cu, etc., and are 5–30 nm thick. The thickness of the nonmagnetic layers  1013  corresponds to the maximum of the exchange coupling field. 
       FIG. 11  is a cross-sectional view along line  6 — 6  of another embodiment of a write element having laminated magnetic studs. This particular embodiment differs from the embodiment of  FIG. 10  in that the magnetic studs  431 ,  432 ,  433 ,  440  and  450  which connect the various yoke portions  410 ,  420 ,  510 ,  520  are also made of laminate material. In other words, the single layer magnetic studs  431 ,  432 ,  433 ,  440  and  450  are replaced with studs formed of laminate material. The ferromagnetic layers  1011 ,  1013  of the studs are made of materials such as Ni45Fe55, NiFeCo, or FeCo. The thin nonmagnetic layers  1012  of the studs are made of Ru, Rh, Re, Cu, etc., and are 5–30 nm thick. The thickness of the nonmagnetic layers  1013  of the studs corresponds to the maximum of the exchange coupling field. The laminate layers are formed by alternating the ferromagnetic layers  1011 ,  1013  and non-magnetic yet conductive layers  1012 . The laminate material is formed by alternately sputtering a non-magnetic layer  1012  and a magnetic layer  1011 . Specifically the laminate material is placed on a turntable and then the non-magnetic layer  1012  and the magnetic layer  1011  are sputtered at the various turntable locations. 
     In one embodiment, the magnetic yoke  400  has a single domain state and is made of antiferromagnetically exchange-coupled superlattices. 
     The resultant write element  300  is a very high speed, high efficiency write element that is used as part of a transducer that includes a giant magneto resistive head. The yoke  400  forming a figure-8 wrap around the coil  310  results in at least twice as much magnetic flux, being induced in the coil for a given write current I W  passing through the coil. In addition to this figure-8 wrap, the structure is unique and yields a write head capable of operating at a high frequency while being highly efficient. 
     Forming the yoke portions  410 ,  420 ,  510 ,  520  of a laminate material also increases the efficiency and speed of the write element  300 . The laminate material keeps a single domain on each layer of the laminate in the magnetic structure. This speeds the flux transmission since less energy has to be expended in flipping magnetic domains. The laminate material merely has a series of coherent spins so that when magnetic flux is induced in a flux path the domains must only be moved slightly rather than flipped. Coherent spinning works by moving the magnetic flux within the layer through a certain number of degrees and never requires a flipping of a domain within the structure itself. As a result, the magnetic flux path is much quicker in transmitting the flux as the laminate provides a structure which enables coherent spinning. The application of antiferromagnetically exchange-coupled superlattices made of altered ferromagnetic and nonmagnetic layers for the yoke formation, stabilizes the single domain structure and increases the effective anisotropy of the yoke, thus reducing the switching time of the write element and increasing recording speed. 
     The yoke portions  410 ,  420 ,  510 ,  520  are each symmetrical. The resultant structure is also symmetrical which allows which provides for exact knowledge of where the flux path will be located. 
     In addition to being symmetrical, the whole structure is short and compact which limits the amount of reluctance of the coils. Since there is a shorter flux path, the magnetic flux only has to travel a short distance in order to be presented at the gap  442 . The short, compact structure results in a low reluctance which is the resistance to changes in magnetization. The low reluctance makes the flux path capable of changing at much higher frequencies so that transitions may be written at higher frequencies and data rates. The structure could be approximately 10–12 microns in height and could be approximately 10–12 microns in width. 
     Since the coil  310  has very few turns, the coil has a low inductance. The coil is basically a single-turn coil. Inductance is proportional to the number of turns in the coil squared. The low inductance allows for the magnetic flux within the flux path to change quickly. In other words, the low inductance enables the flux to change quickly. 
     Still another aspect that makes the write element  300  capable of high frequency operation is that the coil  310  is formed as a transmission line. Still a further advantage is that the properties of U-shaped transmission lines are known and can be easily accommodated by those in the disc drive industry. 
     Advantageously, the write element  300  has a low inductance, because of the number of turns and a low reluctance because it can be made very small. The use of a transmission line for the coil  310  allows for high frequency current somewhere in the neighborhood of 1 megahertz. The use of the laminate for the flux path prevents domains from being flipped, which also takes time. The end result is a magnetic write element that can be used to produce very high rates of data transmission. Data rates of 2 gigabytes per second are achievable using this invention. It is contemplated that much higher write rates may also be achievable. 
     CONCLUSION 
     A thin film transducer includes a coil and a yoke. The coil of the transducer is formed as a transmission line. The coil is U-shaped. The yoke and coil are intertwined to provide more than two flux interactions between the yoke and the coil. The yoke is a planar, symmetrical structure. The yoke also includes a first pole portion made of a laminated material, and a second pole portion made of a laminated material. The laminated material includes a first layer of ferromagnetic material, a second layer of ferromagnetic material, and a layer of nonmagnetic conductive material interposed between the first layer of ferromagnetic material and the second layer of ferromagnetic material. The first layer of ferromagnetic material and the second layer of ferromagnetic material are antiferromagnically exchange coupled to each other through the layer of nonmagnetic conductive material. The first pole portion and the second pole portion are planar. The first pole portion has two ends and the second pole portion has two ends. The first pole portion and the second pole portion are connected to one another between the ends of the first pole portion and the second pole portion. The coil is U-shaped and consists of a single turn. The first pole portion is symmetrical and the second pole portion is symmetrical. 
     A slider includes a magneto resistive read element and a write element. The write element of the slider further includes a coil formed as a transmission line, and a yoke. The yoke is symmetrical and the yoke and coil are intertwined to provide more than two flux interactions between the yoke and the coil. The yoke forms a figure 8 around the coil to provide more than two flux interactions between the yoke and the coil. The first pole portion is made of a laminated material, and the second pole portion is made of a laminated material. The laminated material includes a first layer of ferromagnetic material, a second layer of ferromagnetic material, and a layer of nonmagnetic conductive material interposed between the first layer of ferromagnetic material and the second layer of ferromagnetic material. The two layers of ferromagnetic material in each of the first and second pole portions are separated by a layer of nonmagnetic conductive material. The two layers of ferromagnetic material in each of the first and second pole portions are antiferromagnically exchange coupled to each other through the layer of nonmagnetic conductive material. 
     A disc drive which uses the slider with a magneto resistive read element, and a write element further having a coil formed as a transmission line, and a yoke, also includes a base, a disc rotatably attached to the base, and an actuator assembly attached to the base. The actuator assembly includes the slider. The actuator assembly is adapted to move the slider between selected positions on the disc. The actuator assembly also includes a voice coil motor for moving the actuator assembly, and a control circuit for controlling the movement of the actuator assembly by controlling the amount of current provided to the voice coil motor. The disc drive of also includes a data channel. 
     A transducer includes a magneto resistive read element, and a write element. The write element includes a mechanism for providing a high frequency write current; and a yoke. 
     It is to be understood that the above description is intended to be illustrative, and not restrictive. Many other embodiments will be apparent to those of skill in the art upon reviewing the above description. The scope of the invention should, therefore, be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled.