Planar magnetic ring head for contact recording with a rigid disk

Information

  • Patent Grant
  • 6493191
  • Patent Number
    6,493,191
  • Date Filed
    Friday, September 15, 1995
    29 years ago
  • Date Issued
    Tuesday, December 10, 2002
    22 years ago
Abstract
A transducer for a hard disk drive system has a planar magnetic core and a pair of poletips that project transversely from the core for sliding contact with the disk during reading and writing. The transducer is formed entirely of thin films in the shape of a low profile table having three legs that slide on the disk, the poletips being exposed at a bottom of one of the legs for high resolution communication with the disk, the throat height of the poletips affording sufficient tolerance to allow for wear. The legs elevate the transducer from the disk sufficiently to minimize lifting by a thin air layer that moves with the spinning disk which, in combination with the small size of the thin film head allows a low load and a flexible beam and gimbal to hold the transducer to the disk. The transducer includes a loop shaped core of magnetic material that ends at the poletips, the core extending further parallel than perpendicular to the disk surface and preferably being formed of a plurality of slightly spaced ribbons of magnetic material in order to increase high frequency permeance. A high magnetic saturation layer may be formed adjoining the gap in at least the trailing poletip, in order to avoid saturation at the poletips during writing. The dimensions of the yoke adjacent to the poletips are also designed to avoid saturation at the poletips by saturating at a lower flux in the yoke than the poletips. The close relationship between the transducer and the media of the disk affords high density magnetic data storage and retrieval.
Description




TECHNICAL FIELD




The present invention relates to hard disk drive systems having transducers including a magnetic core with a gap adjacent to a magnetic storage disk.




BACKGROUND OF THE INVENTION




Hard disk drives have traditionally employed electromagnetic transducers that are spaced from a rapidly spinning rigid disk by a thin layer of air that moves with the disk surface. Such an air layer helps to avoid damage between the rapidly spinning disk and the essentially stationary transducer, which is constructed with a large, aerodynamic “slider” designed to “fly” over the surface, buoyed by the moving air layer. The air layer, however, creates an additional space between the transducer and the magnetic medium of the disk that is used to store information. This spacing lowers the density with which data can be stored and lowers the resolution and amplitude with which data can be retrieved.




Conventional flying heads have a pair of poletips formed by thin film processes on a back end of the slider and terminating coextensively with the slider air bearing surface. In flight, the slider is tipped so that the back end is lower than the front end and the poletips are closer to the disk than the remainder of the slider. Other flying heads, representative of which is U.S. Pat. No. 4,698,708 to Lazarri, have poletips that are flush with the air bearing surface of the slider partially between the front and back ends.




In an attempt to lower the spacing loss and thereby increase resolution and amplitude, transducer flying heights have generally decreased over many years in the magnetic recording industry. Lowering the flying height, however, encounters a countervailing problem of catastrophic head crash that occurs when the transducer impacts the rapidly spinning disk. In recent years a solution to the conflict between flying height and head crash has been achieved by designing the drive system so that the head supporting structure is run in continuous sliding contact with the disk, which can reduce the problem of impact between the head and disk and decrease the spacing between the head and disk. Any perturbation that causes separation between the head and disk, however, can result in a crash when the two recontact. Such a perturbation can be due to a shock to the drive, such as would occur from accidental bumping of the drive or its support, or can be due to the presence on the disk surface of an asperity or debris. Note that in either situation, a potentially destructive impact can occur due to the initial perturbation, instead of or in addition to the crash upon recontact.




In U.S. Pat. No. 5,041,932, Hamilton discloses a transducer that operates in contact with a rigid disk surface without destructive head crash, essentially by designing the mechanical and inertial characteristics of the transducer to conform to the rapidly spinning rigid disk without damage to the disk or transducer. A different approach for a hard disk drive system for allowing operational contact between the head and the disk is disclosed in U.S. Pat. No. 4,819,091 to Brezoczky et al., which proposes that nondestructive wear may be possible provided that the slider material is so much more thermally conductive than the disk that the slider surface is maintained at a lower temperature than the much larger disk surface as the slider rubs on the disk. And U.S. Pat. No. 4,901,185 to Kubo et al. teaches operational contact between a disk and a slider having a head appended and spaced from contacting the disk to avoid damage to the head. More recently, U.S. Pat. No. 5,327,310 to Bischoff et al. teaches a transducer similar to that disclosed in the Hamilton patent but having a ring-shaped transducer mounted vertically on a trailing end of a slider that makes intermittent, bouncing contact (“pseudo-contact”) with the disk.




An object of the present invention is to provide a transducer optimized for minimal head-medium spacing during longitudinal recording on and reading from the medium. A related object is for such a transducer to be stable and biased toward contact with a disk surface without the need for excessive force to hold the transducer to the surface against the lifting force of an air layer that moves with the disk, thereby avoiding problems of vibration and damage to the disk and/or transducer. In concert with the above objects it is desired to provide a transducer having efficient electromagnetic signal transduction.




SUMMARY OF THE INVENTION




The above objects are achieved with a transducer shaped like a low-profile table with three short support legs that slide on the medium surface during information transfer between the transducer and the medium. The transducer includes a magnetic core which stretches like a shallow, symmetric loop within the plane of the table, with ends of the loop extending into one of the legs to form a pair of closely spaced magnetic poletips exposed to the disk surfacein close proximity to the medium. Inductively coupled to the core is a conductive coil that spirals in opposite directions around laterally opposed sections of the core, the spirals stacked like pancakes centered on the opposed core sections. The core and the coil extend substantially further in the plane of the table top than along the direction with which the legs project, affording the mechanically and aerodynamically favorable low profile shape. The table top may be T-shaped or trapezoidal, reducing the mass of the transducer and increasing the number of transducers that can be obtained per wafer while retaining three-legged stability.




During writing of information to the medium, a current in the coil creates a magnetic field along the length of the loop shaped core, creating a magnetic field that spans the microscopic gap between the ends of the core and induces a similarly directed magnetic field in the adjacent media layer. Since the poletips are in contact with the disk surface and have an extremely small gap, very high resolution writing of information can be accomplished with this system. Unlike conventional heads which have tight tolerances for vertical throat height, the dimensions of the planar core of the present invention allow the throat height to vary substantially without impeding writing and reading efficiency, affording tolerance for wear of the sliding poletips. Additionally, the planar core allows the head to assume a relatively flat, stable, low-profile conformation with lower moment arms about the head-disk contact area, including both a lower moment of inertia of the chip and a lower effective mounting point of the beam holding the chip.




Reading of magnetic patterns imbued in the medium occurs due to the changing magnetic field seen by the poletips from the spinning disk on which the tips slide, creating a voltage in the inductively coupled coil that is read as a signal. Due to the intimate contact between the poletips and the recording surface, very high signal resolution and amplitude is achieved. In order to increase the high frequency permeance of the head, the core is formed of elongated strips, layers or filaments. Additionally, the poletips may be coated with a high magnetic saturation material adjacent to the gap in order to provide an intense magnetic field across the gap without saturation, even at field strengths of up to and exceeding 10,000 Gauss. In a preferred embodiment, the core is shaped like a clamshell, allowing formation of several coil layers within the core without unnecessarily increasing the reluctance of the core.




The low-profile, three-legged transducer is attached via a gimbal to a load beam to present a dynamic configuration that closely and rapidly conforms to a spinning disk so as to maintain contact and high resolution communication with the medium. Due to the small legs, which act like short stilts lifting the rest of the transducer above the thin moving air layer that adjoins the disk, little of the transducer is impinged upon by that thin moving air layer, and so minimal lifting force is generated that must be overcome to maintain contact. The interconnection between the transducer and the gimbal is made with exposed conductive bumps that pierce and are anchored to an outer insulative layer of the transducer, providing mechanical as well as electrical connections. The transducer is built in layers, along with many other transducers, on the surface of a wafer substrate from which the transducers are later removed, allowing the transducer to be much smaller and lighter in weight than conventional transducers that include bulk substrate materials. The legs, including the magnetically active leg containing the projecting poletips, are formed last, allowing careful tailoring of the most sensitive portions of the transducer.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is an enlarged perspective view of a generally plank-shaped embodiment of a transducer of the present invention with three disk-facing projections.





FIG. 2

is a bottom view of the transducer of FIG.


1


.





FIG. 3

is a cross-sectional view of a magnetically active portion of the transducer of FIG.


1


.





FIG. 4

is an opened up bottom view of the magnetically active portion of FIG.


3


.





FIG. 5

is a further enlarged bottom view of the magnetic pole structure of FIG.


4


.





FIG. 6

is a cross-sectional view of an early step in a fabrication process of the transducer of

FIG. 1

, showing the formation of a conductive etchable release layer for the transducer on a wafer substrate.





FIG. 7

is a cross-sectional view of a later step in the process of

FIG. 6

, showing the formation of a gold interconnect button for the transducer.





FIG. 8

is a cross-sectional view showing a later stage in the process of

FIG. 6

, including formation of an interconnect stud.





FIG. 9

is a cross-sectional view showing a later stage in the process of

FIG. 6

, including construction of magnetic yoke layer, magnetic stud section and conductive coil section.





FIG. 10

is a top view of formation of the magnetic yoke of

FIG. 9

by window frame plating.




FIG.


11


. is a cross-sectional view showing steps in the formation of magnetic stud and conductive coil sections subsequent to those shown in FIG.


9


.





FIG. 12

shows an opened up top view of one of the coil layers formed by the process of FIG.


10


.





FIG. 13

is a cross-sectional view of the formation of an amagnetic pedestal on a layer between ends of the magnetic studs formed by the process of FIG.


10


.





FIG. 14

is a cross-sectional view showing the construction of a magnetic yoke on the layer and pedestal of

FIG. 14

, the yoke having ends extending transversely toward each other.





FIG. 15

is a cross-sectional view showing the formation of a first magnetic pole layer and amagnetic gap structure on the extending yoke ends of FIG.


14


.





FIG. 16

is a cross-sectional view showing the formation of a second magnetic pole layer adjoining the amagnetic gap of FIG.


15


.





FIG. 17

is a cross-sectional view showing angled, rotating ion beam etching of the pole layers to form tapered poletips.





FIG. 18

shows a top view of the pole layers and etch mask of FIG.


17


.





FIG. 19

is a cross-sectional view showing the formation of a hard protective layer on the tapered poletips.





FIG. 20

is a cross-sectional view showing the formation of a layer of high magnetic saturation material on the pole layer adjoining the gap.





FIG. 21

is a cross-sectional view showing the formation of layers of high magnetic saturation material on both sides of the gap.





FIG. 22

is a top view showing the formation of a pair of laminated magnetic studs for connecting top and bottom yokes.





FIG. 23

is a top view showing the formation of an alternative embodiment of laminated magnetic studs.





FIG. 24

is a cross-sectional view of the formation of a laminated top yoke.





FIG. 25

is a top view of the formation of a laminated top yoke of FIG.


24


.





FIG. 26

is a cross-sectional view of a laminated, clamshell shaped magnetic core, including the top yoke of FIG.


24


and the laminated studs of FIG.


22


.





FIG. 27

is a cross-sectional view of a laminated, clamshell shaped magnetic core, including the top yoke of FIG.


24


and without any magnetic studs.





FIG. 28

is a bottom view of a T-shaped chip of the present invention.





FIG. 29

is a top view of a pair of trapezoidal chips of the present invention.





FIG. 30

is bottom view of a flexure beam and gimbal attached to the T-shaped chip of

FIG. 28

to from a head gimbal assembly (HGA).





FIG. 31

is an opened up top view of a disk drive employing the HGA of FIG.


30


.











DESCRIPTION OF THE PREFERRED EMBODIMENT




Referring now to

FIGS. 1 and 2

, a greatly enlarged view of a transducer


20


of the present invention has a generally plank shaped chip


22


with a surface


25


designed to face a recording surface of a rigid magnetic storage disk. The transducer has a magnetically active pad (MAP)


28


that projects from the disk-facing surface


25


at a location adjacent to a first end


30


of the chip


22


and approximately equidistant between a right side


33


and a left side


35


of the chip. A pair of magnetically inactive pads (MIPS)


38


and


40


project from the disk-facing surface


25


adjacent to a second end


42


of the chip


22


, MIP


38


being disposed about the same distance from side


33


as MIP


40


is from side


35


. The three pads


28


,


38


and


40


are spaced apart from each other to provide a stable support structure for the transducer


20


, like a table with three short legs that can maintain contact with any conventional disk surface. An exposed pair of magnetic poletips


44


are located on a bottom surface of MAP


28


, with an amagnetic gap


46


disposed between the poletips


44


. The poletips


44


are ends of a loop-shaped core of magnetic material that is embedded in the chip


22


and not shown in this figure.




As a descriptive aid, a direction generally corresponding to that in which the MAP


28


and MIPS


38


and


40


extend from the surface


25


is termed the “vertical” direction, while an orthogonal direction along the length of the sides


33


and


35


is termed the “longitudinal” direction. A direction orthogonal to both the vertical and longitudinal directions and corresponding generally with an elongated direction of ends


30


and


42


is termed the “lateral” direction. Elements of the chip


22


designed to be closer to a disk are commonly called “bottom” elements while those that will be employed further from the disk are called “top” elements, although a typical disk will have a chip


22


sliding on both disk surfaces. Moreover, as will be seen, the chips


22


are built in layers beginning with the side that will be positioned furthest from the disk, so that during production some “top” elements are formed beneath some “bottom” elements.




The loop-shaped core extends within a transduction section


48


further in the longitudinal direction than in the vertical or lateral direction, and is inductively coupled within that area


48


to a coil which winds repeatedly around the core, as will be seen in greater detail below. The protrusion. of the poletips


44


from the disk-facing surface


25


allows the core to contact the disk, reducing the spacing between the core and the media layer of the disk while lifting the disk-facing surface of the chip


22


from the influence of the thin film of air moving with the disk. As will be seen, the entire chip


22


is constructed of a composite of thin films, and any bulk substrate which was used as a work surface for forming many thousands of such chips is removed after formation of the chips. This thin film composite chip


22


is much lighter than conventional sliders which include bulk substrate, the lighter weight decreasing the inertia of the chip and the power of impacts between the chip and a hard disk, thus reducing the probability of damage.




The chip


22


may have a thickness measured in the vertical direction between the disk-facing surface


25


and an opposed major surface, not shown in this figure, of between about 1 mil and about 5 mils, although other thicknesses may be possible, depending upon tradeoffs such as magnetic constraints and mass. The lateral width of this embodiment of the chip


22


is about 20 mils, although this width can vary by more than a factor of two and is set primarily by the separation of the MIPS


38


and


40


required for stability. The width can be much smaller about the MAP


28


, as discussed below, while still encompassing the transduction section


48


. The MAP


28


and MIPS


38


and


40


extend from the surface


25


an approximately equidistant amount, which may range between about 2 μm and 8 μm, which is sufficient to avoid aerodynamic lifting and to allow for gradual wear without engendering fracturing of those pads or instability of the transducer


20


. The aerodynamic lifting force is believed to be primarily due to the disk-facing area of the chip which is in close proximity with the disk, including the contact area of the pads, and any bowing or tilting of the chip. As will be explained in greater detail below, the chip


22


may be intentionally bowed, tilted and/or etched to create a negative pressure region between the chip


22


and the spinning disk, so that the lifting force from the disk-facing area of the chip is more than overcome by downward force of the negative pressure. An area


50


of each of the MIPS


38


and


40


may be as small as 25 μm


2


or as large as about 1000 μm


2


, although other sizes are possible based upon tradeoffs including, for example, friction, pad wear and manufacturing tolerances. An aspect ratio of the vertical height to the lateral or longitudinal width of those pads should not be much over 2/1 to avoid fracturing and transducer inefficiency. The length of the chip


22


of this embodiment as measured between the first end


30


and the second end


42


is about 40 mils, although this can be varied by a factor of two. This aspect ratio is determined primarily by mechanical considerations regarding the separation of the MIPS


38


and


40


and the MAP


28


, as limited by the space needed for the transduction section


48


.




In

FIG. 3

, a cross-section of the chip that focuses on the transduction section


48


is shown along a cross-section bisecting the MAP


28


, the poletips


44


and the gap


46


. A lower layer


50


which preferably is made of alumina, but which alternatively may be made of another electrically insulative, amagnetic material such as doped silicon, silicon dioxide or diamond like carbon (DLC) forms the disk-facing surface


25


, while a hard, wearable casing


52


which is preferably made of DLC or another hard amagnetic material such as silicon carbide or boron nitride forms the portion of the MAP


28


surrounding the poletips


44


. The gap


46


is preferably formed of an insulative, amagnetic material such as silicon or silicon dioxide which is softer than the hard wear material of the casing


52


. Hydrogenated carbon is a desirable gap


46


material, having a hardness that can be adjusted to correspond with the particular poletip


44


, casing


52


and disk surface characteristics. The wear material of the casing


52


is preferably made of an amorphous material such as DLC which has a hardness similar to that of a surface layer of the disk with which the transducer


20


is to be employed, for matching wear between the transducer and the disk. The casing may be thicker closer to the disk-facing surface


25


for manufacturing and durability. Adjoining the poletips


44


is a bottom yoke


55


of magnetic material which extends symmetrically from a pair of slanted sections


58


to a pair of generally planar sections


60


. The poletips


44


and yoke sections


58


and


60


are formed from permalloy or other known magnetic materials, while at least one of the poletips may include a high magnetic moment material, such as cobalt niobium zirconium (CoZrNb), iron nitride (FeN) or iron nitride alloys such as FeNA


1


adjacent to the gap


46


. The yoke sections


58


and


60


are preferably formed in a laminated fashion, to be described below, in order to reduce eddy currents that impede transducer efficiency at high frequencies. Adjoining the yoke sections


60


are a pair of magnetic studs


61


and


62


that extend to a generally planar magnetic top yoke


64


interconnecting the studs


61


and


62


. The poles


44


, bottom yoke


55


, studs


61


and


62


and top yoke


64


form a generally loop-shaped magnetic core


66


, creating a contiguous magnetic circuit except for the small amagnetic gap


46


. In a preferred embodiment discussed below, the studs are eliminated, and the core is formed in a shape having a cross-section that resembles a clamshell.




A series of electrically conductive coil sections


70


made of copper or other conductive metals or alloys is shown in cross-section in

FIG. 3

to be spaced both within and without the magnetic core


66


. Interspaced between the coil sections


70


and the core


66


is an electrically insulative spacer material


72


such as Al


2


O


3


, Si O


2


or a hardbaked photoresist or other polymer. The coil sections


70


can be seen to be divided into three generally horizontal layers in this embodiment, although more or less layers are possible, depending upon manufacturing and magnetic tradeoffs. These layers of coil sections


70


can also be seen to fall into four horizontally separate groups. Proceeding from left to right, these groups are labeled


74


,


76


,


78


, and


80


, with a crossover section


82


connecting groups


76


and


78


. Although difficult to see in the cross-sectional view of

FIG. 3

, the coil sections


70


are in actuality a single coil


84


which winds repeatedly about first one and then the other of the two studs


61


and


62


. The groups


74


and


80


which are disposed outside the core


66


have an electric current during writing or reading which is directed into or out of the plane of the paper opposite to that of groups


76


and


78


and crossover section


82


. The reader may wish to jump ahead temporarily to

FIG. 12

, which shows a top view of one layer of the spiraling coil


84


, including crossover


82


.




Thus a current traveling into the plane of the paper at coil section


86


would spiral in the layer of that section


86


around stud


61


with a generally increasing distance from the stud


61


until reaching section


88


, which is connected to section


90


of the next layer. The current would then spiral inwardly about stud


61


in the layer of section


90


until reaching section


92


, which is connected to section


94


of the next layer. The current would then spiral outwardly around stud


61


in the layer that includes section


94


until reaching crossover section


82


, at which point the current would begin to spiral inwardly about stud


62


, traveling to the second layer at section


95


. The layered spiraling of the current around stud


62


would continue in a similar but converse fashion to that described above for the spiraling about stud


61


, until the current exited the coil structure by traveling out of the plane of the paper at section


96


. The coil


84


thus resembles interconnected stacks of pancake-shaped spirals centered about studs


61


and


62


.




Representative dimensions for this embodiment include an approximately 3 μm thick bottom yoke


55


and a top yoke


64


that is about 4 μm in thickness, and studs


61


and


62


which each extend vertically about 23 μm between the yokes. The thickness of the bottom yoke


55


is selected to saturate at a somewhat lower magnetic flux than the poletips, thus limiting the flux through the poletips and avoiding broadening of the transistion that would occur during poletip saturation. In order to achieve this flux limiting effect with poletips of different sizes and materials, a function can be employed to determine the optimum bottom yoke parameters. The individual coil sections


70


are about 3.5 μm thick measured in the vertical direction, and have a center to center spacing of about 5.5 μm in that direction. Longitudinally, those sections


70


may be about 2 μm to 4 μm thick within the core


66


with a center to center spacing of about 4 μm. The top yoke


64


extends about 169 μm longitudinally, and the bottom yoke


55


extends similarly but is, of course, split up by the poletips


44


and gap


46


.




In

FIG. 4

, a top view diagram of the magnetic core


66


shows that the bottom yoke


55


is shaped like a bow-tie, as the slanted sections


58


are much narrower in lateral dimension than the planar sections


60


. Diagonal tapered portions


100


of the planar sections


60


funnel magnetic flux into the narrower section


58


during a write operation and offer a low reluctance path for such flux during a read operation. Centered atop the slanted sections


60


are the poletips


44


, which are separated by the amagnetic gap


46


. The planar sections


60


have a width, excluding the tapered sections


100


, of about 42 μm, which tapers at about a 45 degree angle to a width of about 7 μm at the slanted sections


58


. The studs


61


and


62


meet the planar sections


60


distal to the poletips


44


.




An even more enlarged view in

FIG. 5

shows that the poletips


44


are shaped like baseball homeplates that nearly meet along parallel sides, separated by the long, narrow gap


46


. The poletips


44


and gap


46


are exactingly tailored to precise dimensions that are chosen based on a number of parameters. The specific embodiment depicted in

FIG. 5

has poletips that each measure 3.25 μm in the lateral dimension and 4 μm in the longitudinal direction, before tapering to extend another 2 μm longitudinally. The peak-to-peak longitudinal dimension of the poletips


44


and gap


46


is 12 μm. The gap


46


has a recisely defined longitudinal dimension of 0.26 μm and a lateral dimension of 3.25 μm.




Beginning with

FIG. 6

, a process for making the chip


22


is shown. Atop a ceramic wafer substrate


110


such as silicate or hot pressed Al


2


O


3


/TiC which has been cleaned and of which a small portion is shown, a sputtered seed layer


112


of titanium copper (Ti/Cu) of between about 1000 Å and 2000 Å is formed in two steps, by first sputtering a layer of Ti and then sputtering a layer of Cu. The seed layer


112


allows electroplating of a copper (Cu) release layer (“CuRL”)


114


which merges with the seed layer


112


. The CuRL


114


provides, as will be seen, eventual release of a large number of formed chips


22


from the substrate


110


. Other selectively etchable conductive materials could instead be used, but copper offers a highly conductive, cost effective choice for this purpose. The CuRL


114


is formed to a thickness of about 25 μm or 1 mil and is then annealed and lapped and cleaned to form a planar surface for building the chip


22


. The term “lapping” is used in the present invention to describe at least somewhat abrasive rubbing or polishing of a surface that removes irregularities and provides a smooth, planar surface, while generally reducing the thickness of a layer a predictable amount. Forming such planar surfaces on layers that may contain various portions of discrete elements is important for accurate construction of the chip


22


from a number of layers.




Instead of employing a release layer for removal of the chips


22


from the wafer, the wafer may be selectively etched to free the chips. For example, a silicon (Si) wafer may be sputtered with an alumina layer that is to become a side of the chip


22


facing away from a disk. That alumina (Al


2


O


3


) layer is then chemically etched to form holes for a pair of gold interconnect buttons that provide electrical leads between the transducer


20


and the disk drive. A reactive ion etch (RIE) is then performed with CF


4


/O


2


to extend the holes into the silicon wafer, after which a seed layer is sputtered on the alumina and through the holes. A photoresist mask is then formed surrounding and having a greater diameter than each hole, and then a layer of gold is electroplated to a thickness that substantially exceeds the alumina thickness, so that the gold extends through the holes and protrudes from each side. After the remaining layers of the chips


22


are formed, as will be described in detail below, the wafer is selectively etched, leaving the thin film chips. Optionally, prior to etching most of the wafer can be ground away, leaving about 2 mils of silicon attached to the alumina layer and gold buttons. While the chips


22


are protected with a photoresist or other covering, the remaining Si wafer is removed with another RIE etch, thereby freeing the chips.




Returning in

FIG. 7

to the process flow that employs a release layer, atop the polished CuRL


114


an adhesion layer


115


of titanium (Ti) is formed, on which a layer


116


of alumina is deposited, although other electrically insulative, amagnetic materials such as silicon dioxide (Si O


2


) may instead be employed for layer


116


. The adhesion layer


115


keeps the CuRL


114


and alumina layer


116


from separating, like a double sided atomic sticky tape, for which materials other than Ti could alternatively be used, such as chromium (Cr) or nickel iron (NiFe). After lapping to leave about 4 μm thickness and cleaning, the alumina layer


116


is etched to form an interconnect orifice


118


, while other similar orifices are formed at this time for test pads, not shown. This etching is preferably accomplished with phosphoric acid (H


3


PO


4


) through a Ti mask which has been sputtered onto the alumina surface and photolithographically patterned and etched. Ion beam etching (IBE) is then performed through the Ti mask in order to extend the orifice


118


partially into the CuRL


114


, although the test pad orifices are covered at this time so as to avoid their extension. A gold (Au) button


120


is then electroplated in an area overlapping and filling the orifice


118


and the test pad orifices adjoining the CuRL


114


, the button


120


having a vertical thickness near its center of about 15 μm, and spreading laterally and longitudinally a significant extent. To ensure that the button does not spread too far, a photoresist mask can optionally be formed atop the alumina


116


to define a border around the button


120


. Another alumina layer


122


is then deposited, and then lapping is performed to the extent of dashed line


125


, leaving the gold button


120


anchored to the alumina


116


and forming a flat surface along line


125


, upon which additional layers of the transducer are to be formed.




When CuRL


114


is later removed to release a finished or nearly finished chip


22


, a protrusion


127


of the gold button


120


beyond the alumina layer


116


will afford a conductive path to the transducer


20


for a suspension or support, while another similar conductive button, not shown, offers a return path for electrical current and potential. These buttons offer structural as well as electrical connections between the chip


22


and the suspension that allow appreciable torque about the lateral and longitudinal directions, which is beneficial in allowing the chip to conform to the spinning disk surface. A third gold button, also not shown, is formed at a location spaced apart from the other buttons to provide another mechanical connection for the chip. The lateral and longitudinal extension of the button


120


, and the similar extension of other buttons that are not shown, in what will become the interior of the chip


22


anchors those connective buttons to the chip.




Referring now to

FIG. 8

, atop the planarized conductive button


120


a 2500 Å thick layer of Ti is sputtered, which is then patterned using a photoresist mask and ion beam etched to remove unwanted Ti, forming an anti-seepage layer (ASL)


130


which extends laterally and longitudinally beyond the button


120


. The IBE also forms target patterns of Ti, not shown, near the perimeter of the wafer for alignment of later steps in the fabrication process. The ASL has been patterned to leave an opening adjoining a middle of the button


120


, which is now plated with a copper layer to form an interconnect stud


133


. Optionally, a seed layer of Ti/Cu and photoresist plate through mask may first be formed in order to ensure uniform plating of the copper layer, after which the photoresist is removed and then the exposed Ti/Cu seed layer is removed by IBE. An approximately 9 μm thick alumina isolation layer


135


is then deposited and then lapped flat and cleaned to leave a flat surface including an exposed top of the interconnect stud


133


.





FIG. 9

shows the formation of the top yoke


64


on the alumina isolation layer


135


, beginning with the deposit of an electroplating seed layer


138


to a thickness of about 1000 Å. The seed layer


138


is then examined for roughness with a laser surface profiler, as it is important for the formation of the top yoke


64


that roughness of the isolation layer


135


and adjoining seed layer


138


be minimized, in order to reduce noise and increase the efficiency of the top yoke.




As shown in

FIG. 10

, the area for the top yoke


64


is then defined by window frame plating, including lithographically forming a resist border


141


of the top yoke on the seed layer


138


. The top yoke


64


is then electroplated with NiFe, along with an uncovered area


142


of the seed layer


138


outside the border


141


. A laterally directed magnetic field is applied during the electroplating to create magnetic anisotropy in the NiFe yoke


64


having an easy axis of magnetization along the direction of the applied magnetic field, and thereby improve the magnetic characteristics of the top yoke


64


. The photoresist border


141


is then removed, and the seed layer


138


that had been covered by that border


141


is thereafter removed by IBE, which also removes a small fraction of the electroplated yoke


64


and outside area


142


. Another photoresist mask, not shown, is then formed covering the yoke


64


and extending over a portion of the exposed area which had formerly contained the seed layer


138


that was protected from plating by border


141


. The electroplated area


142


not covered with the photoresist mask is then etched away and then the mask removed to leave yoke


64


. Window frame plating is employed repeatedly in the current invention to form magnetically permeable elements, which typically involve electroplating NiFe using fairly uniform current densities onto seed layers such as layer


138


. The top yoke


64


is preferably formed of “permalloy”, which is a NiFe alloy composed of about 80% nickel and 20% iron, by weight, although many other magnetic materials can be used. The top yoke


64


is then examined with energy dispersive X-rays (EDX) to determine the atomic composition of that yoke.




Referring again to

FIG. 9

, atop the seed layer


138


separate from the top yoke


64


another layer of copper is then plated through a different photoresist pattern exposing stud


133


to form a conductive up lead


140


while the top yoke


64


is covered with photoresist. After removal of the photoresist, an ion beam etch is then performed to remove the seed layer


139


disposed between the top yoke


64


and the up lead


140


. A wet “Phillips etch” with dilute hydrogen sulfide (H


2


SO


4


) and hydrogen peroxide (H


2


O


2


) then removes any remaining NiFe not protected with photoresist. In an alternative process, not shown, the seed layer for the up lead


140


can be formed of Ti/Cu in a separate step from the seed layer for the top yoke


64


rather than being simultaneously formed of the NiFe or MoNiFe seed layer used to plate that yoke. Another alumina layer


137


is formed and lapped to expose the up lead


140


and the top yoke


64


. A seed layer


139


of nickel iron (NiFe) or molybdenum nickel iron (MoNiFe) is formed on the top yoke


64


, the up lead


140


and the alumina layer


137


. A photoresist layer, not shown, is then patterned to leave exposed portions of the top yoke


64


for electroplating a pair of magnetic return studs, of which return stud


62


is shown. The return stud


62


is formed by electroplating through a photoresist pattern, the return stud then being examined by EDX to ensure appropriate atomic composition. Another photoresist layer is then patterned that leaves exposed two areas of the up lead


140


for electroplating a pair of copper studs. This pair of studs comprises a center tap stud


144


, which is formed on the up lead


140


adjacent to the top yoke


64


, while a test stud, not shown in this figure, is formed for testing purposes. Another layer of alumina


148


is then deposited, which is then lapped flat and cleaned to expose the magnetic return stud


62


, center tap stud


144


and the test stud, not shown in this figure.




In

FIG. 11

similar process steps are employed to form a first coil layer atop the alumina layer


148


and center tap stud


144


, and to extend the magnetic return stud


62


. To form the coil layer and in other situations for which the formation of high quality magnetic material is not necessary, a process termed “through plating” is typically employed rather than window frame plating. The process of through plating differs from window frame plating primarily by exposing via a photoresist mask and electroplating only those areas in which permanent elements are to remain, whereas window frame plating also exposes and plates additional areas, which later need to be removed.




A seed layer


150


of NiFe or MoNiFe is deposited and then coated with a photoresist layer, not shown, which is photolithographically patterned and selectively removed in areas to allow Cu electroplating of the coil section


96


, which is atop the center tap stud


144


, along with coil sections


152


,


153


,


155


and an array of other coils sections, not shown in this figure. After Cu electroplating, the layer of photoresist that had allowed exposure of the coil sections


96


,


152


,


153


and


155


is removed and another photoresist layer is deposited and selectively developed to leave exposed a portion of the seed layer


150


above the magnetic stud


62


. Another layer of the magnetic stud


62


is then formed by window frame plating of permalloy on the exposed (Mo)NiFe seed layer


150


. Another layer of photoresist is then formed, leaving an area above the coil section


155


exposed for plating. A copper interconnect stud


158


is then electroplated on the top of section


155


to provide an electrical connection between the coil layer shown in

FIGS. 10 and 11

and the second coil section, not shown in these figures. After the photoresist has been removed, the seed layer


150


exposed between the magnetic studs


61


and


62


and the various coil sections including sections


96


,


152


,


153


and


155


is removed by IBE or similar process to electrically disconnect the various studs and sections. Another layer of alumina


160


is then sputter deposited and lapped to form a flat surface exposing interconnect stud


158


and magnetic studs


61


and


62


, the surface then being cleaned to prepare for the formation of another similar coil layer along with another extension to magnetic studs


61


and


62


. The wafer may optionally be heated for a few hours at a few hundred degrees C° at about this point in the process, and additionally at later processing stages, to expel moisture or other contaminants from the layers.




The formation of the second and third layers of coil spirals and magnetic stud extensions proceeds along similar lines as that explained above with regard to the first coil layer, the detailed description of which is omitted for brevity. It should be noted that an array of approximately ten thousand transducers are formed simultaneously on a six inch diameter wafer, and in each of the layers of coil spirals a few positions of this array are devoted to test structures rather than working transducers.




In

FIG. 12

, a top view of the third layer of coil


84


shows that these coil sections are part of a coil spiral


156


that winds repeatedly around the magnetic return stud


62


, while another coil spiral


157


winds in an opposite direction around magnetic stud


61


, the spirals


156


and


157


connected at a crossover


82


. As mentioned previously with reference to

FIG. 3

, these spirals are connected at sections


94


and


95


to the second layer of coil spirals, which are connected to the first layer of coil spirals, which are connected via interconnect studs


133


and gold buttons


120


to provide electrical contact with the drive system.




Between the third layer of coil spirals and the bottom yoke an electrical isolation layer


170


shown in

FIG. 13

is formed of a layer of alumina. Note that extensions for the magnetic studs


61


and


62


are first formed, by the seeding, photolithography and electroplating process described earlier. Similarly, a pair of copper test leads are formed at this level and lead away from the coils to provide connections for a probe, not shown, to test the transducer. After formation of the studs


61


and


62


, the leads and the alumina layer


170


, lapping and cleaning are performed so that the layer has an approximately 5 μm thickness and a smooth, clean surface.




In

FIG. 13

, atop the smooth surfaced isolation layer


170


, a pedestal


178


is formed in order to elevate a portion of the magnetic core, including the poletips


44


. The pedestal


178


may be formed by a variety of methods of which a preferred example involving chemical etching will now be described. A silicon carbide (SiC) etch stop layer


180


having a thickness of about 4000 Å is first sputter deposited on the wafer in order to protect the alumina layer


170


during etching to form the pedestal


178


, which is also formed of alumina. A layer of alumina


177


which is to form the pedestal


178


having a thickness of about 12 μm is then sputtered, atop of which a stressed, high bias layer


179


of alumina about 0.5 μm thick is optionally formed, which etches faster than the thick alumina layer


177


. This etching is performed by first depositing a metal etch mask of MoNiFe to a thickness of about 500 Å, on top of which a layer of photoresist


185


is applied and patterned. Exposed areas of the MoNiFe are then removed and the resist is hardbaked for rigidity, leaving a rectangular area


182


protecting the top of the pedestal, a small side of this area


182


being shown in this cross-sectional view. The 12 μm thick layer of alumina is then chemically etched with a solution of HF diluted to 15% by volume, although other chemical etchants may be alternatively employed, until the SiC layer


180


is exposed. Nearly completed etching of the pedestal


178


is shown in

FIG. 13

, which will result in a peaked pedestal having sides


188


that slope at an angle of 40° to 60° and are symmetrically disposed between the studs


61


and


62


. The angle of the pedestal sides


188


is important in controlling the magnetic separation and area of the bottom yoke adjacent to the poletips


44


, which is important in optimizing the magnetic performance. Control of pedestal side


188


slope is important for achieving a desired thickness and stress of the plated NiFe bottom yoke for magnetic stability. The photoresist


185


and metal mask


182


fall from the pedestal and are removed once the bias layer


179


has completely disintegrated. A reactive ion etch (RIE) preferably utilizing a CF


4


/O


2


plasma is then employed to remove the SiC etch stop layer


180


, except for a portion of that layer disposed beneath the pedestal


178


.




Referring now to

FIG. 14

, atop the studs


61


and


62


, the alumina isolation layer


170


and the pedestal


178


, a seed layer


190


of (Mo)NiFe is deposited to a thickness of about 1000 Å. A photoresist layer, not shown, is then patterned to leave exposed the seed layer


190


in the desired shape of the bottom yoke


60


(see FIG.


4


), outlined by a “window frame” of photoresist with additional areas of the seed layer covered for the later formation of copper studs. An approximately 3 μm thick layer of permalloy is then electroplated atop the seed layer


190


to form the bottom yoke


60


, blanketing the peaked pedestal


178


, after which the photoresist is stripped from the wafer. The thickness of the bottom yoke


60


is important to the saturation and overwrite performance of the transducer, as the yoke


60


is designed to saturate at a flux level slightly below that which would cause the poletips


44


to saturate, keeping the poletips from saturating and therefore keeping the magnetic field at the poletips from broadening. Another layer of photoresist is now deposited and patterned to leave exposed areas of the seed layer


190


for forming copper studs having a thickness of about 14 μm, not shown, that are connected to the copper test leads which are in turn connected to the coil


84


, to allow wafer level testing of inductance and resistance of the coil. The photoresist is then removed, followed by IBE removal of the seed layer that is not covered by the yoke


60


or test studs, and then a wet etch removal of the permalloy left in the “field” outside the window frame, after which the yoke and studs are again covered with photoresist, which is thereafter stripped. The wafer surface is then coated with a layer of alumina


195


that is thick enough (at least about 15 μm) to be nowhere lower than any of the protruding elements such as the pedestal


178


or copper test studs. The wafer is then lapped sufficiently to separate the yoke


60


by exposing the pedestal


178


, obtaining the form shown in FIG.


14


. The size of the yoke


60


separation is carefully controlled to be approximately 3 μm in this embodiment, as a smaller separation can lead to magnetic flux crossing between the yoke


60


rather than the gap


46


, while a larger separation can constrict the flow of flux between the yoke and the poletips


44


.




In

FIG. 15

the formation of the poletips


44


atop the yoke


60


and pedestal


178


begins with the deposit of a seed layer


199


of NiFe, which is then masked, plated and etched by window frame plating to form a first pole layer


202


of permalloy or other magnetic material. A layer


205


of amagnetic material such as hydrogenated carbon (HC


x


), SiC or Si is then deposited, which will become the amagnetic gap


46


between the poles


44


. Although the layer


205


of amagnetic material that forms the gap


46


is formed on an essentially vertical side of the pole layer


202


that is at least several microns in height, a uniform thickness of amagnetic layer


205


is formed on the side of layer


202


adjoining the gap


46


by sputtering in a vacuum chamber while positioning the platform holding the wafer on which the transducers are being formed such that the sputtered material impinges the gap side of the pole layer


202


as well as the top of that layer. This uniform formation on a vertical edge can be accomplished by rotating or transporting the wafer across the base of the sputtering chamber, or simply by positioning the wafer at a location at which the sputtering material has an angled approach. To avoid recession of the pole


44


material relative to the gap


46


during operation and, conversely, to avoid excessive wear of the gap


46


relative to the poles


44


, it is desirable that the gap


46


material have a hardness similar to or slightly less than that of the poles


44


. For this reason Si is a preferred material for layer


205


. The layer


205


is then masked with a photoresist layer


208


that has been patterned so that etching with IBE along mask edge


210


leaves the gap


46


above the pedestal, but removes the portion of the silicon layer that had been covering a portion of the yoke


60


. The dimensions of the gap


46


will set the magnetic resolution during communication between the transducer and the disk, the width of the gap


46


being uniform and typically between about 0.05 μm and 0.4 μm, and preferably about 0.26 μm currently. In

FIG. 16

the patterned photoresist layer


208


has been removed and a second pole layer


212


has been formed by window frame plating or sheet plating adjoining the gap


46


and atop silicon layer


205


. The silicon layer


205


and the portion of the second pole layer that was plated on top of the first pole layer


202


are then removed by lapping to leave a planar surface composed of the first and second pole layers


202


and


212


and the gap


46


.




Referring now to

FIG. 17

, a photoresist mask


215


, shown also in a top view in

FIG. 18

, has been formed in the elongated hexagonal shape desired for the poletips


44


and gap


46


, however, the mask


215


is larger than the eventual poletip area, to compensate for removal of a portion of the mask during etching. The etching is done by IBE with the ion beam directed at a preselected angle a to the surface of the pole layers


202


and


212


, while the wafer is rotated, in order to form vertical sides of the poletips


44


, aside from a tapered skirt


213


, shown in

FIG. 19

, of the poletips


44


, the skirt


213


acting as an aid to the subsequent formation of the hard wear material


52


that will surround the poletips. The vertical sides of the poletips


44


allows operational wear of the poletips to occur without changing the magnetic read write characteristics of the head. On the other hand, the skirt


213


allows the wear material


52


that wraps around the poletips


44


to be formed without cracks or gaps which can occur, for example, in depositing DLC, preferably by plasma enhanced chemical vapor deposition (PECVD) onto a vertically etched pair of poletips


44


. Although this tapered skirt


213


can be achieved by a variety of techniques, an angled, rotating IBE is preferred to exactingly tailor the vertical poletips


44


with tapered skirts


213


.




The photoresist mask


215


has an etch rate that is similar to that of the NiFe poletips


202


and


212


, so that when the angle a is approximately 45° the pole layer


212


and the mask


215


are etched a similar amount, as shown by dashed line


218


. Pole layer


202


, however, is partially shielded from the angled IBE by the mask


215


, so that a portion


220


of layer


202


that is adjacent to the mask is not etched, while another portion is etched as shown by dashed line


222


. As the wafer substrate is rotated, not shown, pole layer


212


will have a non-etched portion


225


adjacent to an opposite end of the elongated mask


215


, as will areas


227


and


228


adjacent sides of the elongated mask. Since areas


227


and


228


are adjacent larger widths of the mask


215


than areas such as


220


and


225


and are thus more shielded and etch slower, the rotation of the wafer is preferably slower during periods when the IBE is angled along the elongated length of the mask (closest either to portion


220


or


225


). The angle a may be changed to further control the shaping of the poletips


44


, for example to employ a greater angle such as about 60° toward the end of the IBE. This rotating, angled IBE is continued for an appropriate time to create a pair of poletips


44


having vertical sides with a tapered skirt


213


and a flat, elongated hexagonal top centered about the gap


46


.




After electrical testing, the wafer carrying the transducer is ready for the formation of the support pads


28


,


38


and


40


, as shown in

FIG. 19

, which focuses on the MAP


28


for clarity. An adhesion layer


230


of Si is deposited to a thickness of about 500 Å atop the poletips


44


and alumina layer


195


. A layer


233


of DLC is then sputtered onto the adhesion layer


230


. An approximately 1500 Å thick layer


235


of NiFe is then deposited, which is then patterned by IBE with a lithographically defined photoresist mask


238


to leave, after IBE, a NiFe mask disposed over the DLC covered poletips


44


and over portions of the DLC layer at positions corresponding to the MIPS


38


and


40


, not shown in this figure. The DLC layer


233


covered with the NiFe masks is then reactive ion etched with


02


plasma to leave projections of DLC that form the MAP


28


and MIPS


38


and


40


. The MAP


28


and MIPS


38


and


40


are then lapped to expose the poletips


44


. The MAP


28


and MIPS


38


and


40


are next protected with a photoresist which extends laterally and longitudinally beyond the edges of each pad, and then an RIE etch using CF4/O2 removes the Si layer


230


not covered by the resist, leaving a flange of Si which helps to position undercutting of the alumina layer


195


further from the MAP and MIPS, resulting in a stronger MAP and MIPS that are thicker closer to the disk-facing surface. The chip


22


is then laser scribed to provide lateral and longitudinal separations from other chips that have been simultaneously formed on the wafer substrate


110


. The above described process has produced chips having the ability to write and read at densities approaching one gigabit per square inch, while variations to this basic chip design offer performance improvements.




As mentioned above, several techniques can be employed to increase the tendency of the chip to maintain contact with a disk, even at high speeds. Warping of the chip can be achieved by stressing the first-formed layer or several layers of the chip, so that upon release from the wafer substrate those layers, which are disposed away from the disk, expand, causing the disk-facing surface of the chip to be slightly concave. This concave disk-facing surface tends to form a negative air pressure region between the chip and the disk, holding the chip to the disk. Another means for creating such a negative air pressure region includes etching a recession in the disk-facing surface, preferably in a region spaced apart from the transduction section


48


. Similar negative pressure effects can be achieved by tilting the chip so that the edge of the chip which first encounters a given portion of the spinning disk and adjoining air layer is spaced closer to the disk than the downstream edge of the chip. Typically the MIPS


38


and


40


are disposed upstream of the MAP


28


, and so such tilting can be effected by tapering the MIPS so that they have an initial wear rate which is greater than that of the MAP, thus shortening the MIPS compared to the MAP. This difference in intial wear rate can be accomplished by forming the MIPS with a smaller area of DLC layer


233


than layer


195


, for example. After the initial thinner portion of the MIPS has been worn away, either by lapping or by employment in a drive, the MIPS are designed to have a vertical wear rate equal to that of the MAP, maintaining the desired tilt of the chip. Similarly, one of the MIPS


38


or


40


which is to be positioned during operation further from the center of a disk than the other MIP, can be designed to have a tapered shape resulting in a faster initial wear rate so that when the chip is disposed near a rapidly spinning outer radius of the disk, a skew of the chip relative to the airflow causes the upstream corner of the chip to be tilted closer to the disk, holding the chip to the disk. This technique is especially useful in larger form factor disk drives, where the tendency to fly at an outer diameter of the disk is greater.




Means for performance improvement include increasing the permeance of the magnetic core, which may be accomplished by laminating the yokes, as shown in

FIG. 20

, including forming a thin amagnetic layer


265


between the formation of first and second magnetic layers


267


and


270


, respectively, to construct a laminated bottom yoke


272


. Lamination of the magnetic core is believed to increase the magnetic flux-carrying capability of the core, particularly at high frequencies, by increasing the proportion of the core which carries magnetic flux. With changing magnetic fields, electrical eddy currents can occur in a skin layer of the conductive magnetic core material that in turn create magnetic fields in the core inward of the skin layer that counteract the desired magnetic fields. Division of the core into strips, layers or filaments increases the proportion of flux-carrying skin layer as compared to nullified inner core, increasing the overall permeance of the core. Division of the core to smaller sizes than necessary to remove the nullified inner core can, however, reduce the overall flux-carrying capability of the core, as amagnetic spacer material begin to replace the flux carrying skin layer. An optimum thickness of the skin layer depends upon factors such as the conductivity and permeability of the core material, and is generally inversely proportional to the square root of the frequency, which may be on the order of 50 MHz, so that an optimum skin layer for the core of the preferred embodiment is on the order of 1 μm.




Another way to improve performance, particularly during writing, involves employing a high magnetic saturation (B


s


) material such as cobalt zirconium niobium or FeAl(N) for a layer of the poletips


44


adjoining the gap


46


, thus ensuring a high intensity magnetic flux adjacent to the gap for increased magnetic field gradients and high resolution writing. A high magnetic saturation (B


s


) or high moment material is generally defined, for the purpose of this application, as one that does not saturate at field strengths greater than 10,000 Gauss. One means for constructing a high B


s


layer along a side of a poletip adjoining the gap is shown beginning in FIG.


20


. After depositing and planarizing an alumina layer


275


, a first pole section


277


of permalloy or other conventional magnetic material is formed by window frame plating, on the top and side of which is formed an approximately 1000 Å thick layer of a high moment material


280


(from the group mentioned above or other high B


s


materials) by sputtering at an angle, as shown by arrows


281


. A vertically directed IBE (normal to the wafer surface) is then performed to remove the essentially horizontal sections


282


of layer


280


disposed atop alumina layer


275


and pedestal


285


, while most of an essentially vertical layer


288


of high B


s


remains after the IBE.




In

FIG. 21

an amagnetic gap


290


has been formed adjoining the film


288


of high B


s


material


288


by the method described above, after which another layer


292


of high B


s


material is sputtered at an angle to cover a side of the gap


290


as well as the top of the first pole section


277


and alumina layer


275


. This high B


s


layer


292


also serves as an electroplating layer for a second magnetic pole section


295


, which may be formed of permalloy. After planarizing, not shown in this figure, to expose the gap


290


, a high moment layer thus adjoins both sides of the gap, providing a much higher saturation field for writing as well as a harder or otherwise more durable structural material that maintains a sharply defined gap despite wear for continued high resolution. Alternatively, since a high moment material is needed for increasing the saturation level of flux adjacent to the gap for writing, and so for writing only needs to be formed adjoining a downstream side of the gap relative to the moving media, only the downstream poletip needs to be coated with the high moment material. This high moment coating may be formed by a similar process as employed to form the gap or the high moment layer


288


, which were described above and will be omitted here for brevity.




As mentioned above, another means for increasing the efficiency of the transducer involves laminating some or all of the core, which may be employed in concert with the above described high moment material


280


adjoining the gap


46


. This division of the core is accomplished in the present invention by forming each of the magnetic yokes in a pair of layers, the layers each having a thickness of about 1.5 μm to 2.0 μm and separated by an approximately 0.1 μm thick amagnetic (preferably alumina) space, rather than the approximately 3 μm thickness of solid yokes


55


and


64


described above. Similar division is accomplished with the magnetic studs by forming a group of at least a few separated magnetic areas in each of the layers that are stacked to form the studs, rather than the solid magnetic studs


61


and


62


described above.




A top view of a layer including a pair of laminated studs


296


is shown in

FIG. 22

to include a number of magnetic slats


297


each having a width W of about 3 μm and a length L of about 10 μm, the slats being separated by amagnetic material similar in dimensions to the slats, so that the overall width A of each stud


296


is about 31 μm and the overall length B of the studs is about 25 μm. The slats


296


may be formed of permalloy or other magnetic material, and are separated by approximately 3 μm of hardbaked photoresist. A series of generally identical stud layers is stacked to form the pair of complete studs that connect the laminated yokes or, as discussed below, a single laminated stud layer may connect the yokes.

FIG. 23

shows an alternative construction of a layer of magnetic studs


298


utilizing strips


299


of magnetic material separated by hardbaked, amagnetic photoresist spacers. The overall dimensions A and B of each stud


298


in the layer are approximately 31 μm and 20 μm, respectively. Each strip


299


has a length of about 31 μm and a width of about 4 μm, and is separated from an adjacent strip


299


by about 4 μm of resist.




Beginning with

FIGS. 24 and 25

, the construction of an alternative and preferred embodiment of the current invention is shown which employs a curved, clamshell shaped magnetic core having shorter magnetic studs formed by a single stud layer, the space needed for the several layers of inner coils being provided instead by curving of the top and bottom yokes. The construction of this embodiment of the transducer proceeds essentially as described before except for the formation of the clamshell shaped core, which begins with the formation, atop the alumina isolation layer


135


, of an etch stop layer


300


of SiC. The etch stop


300


is pierced by an interconnect stud


303


, and has an alumina layer


305


formed thereon. The insulative, amagnetic layer


305


is masked with a photoresist patterned to expose areas at which the core and coils are to be formed, so that after essentially isotropic etching with dilute HF (similar to that employed to create the pedestal beneath the poles) a pair of plateaus


308


having sloping sides remains above the etch stop layer


300


, separated by a recessed area


310


at which the etch stop layer


300


is exposed. The plateaus


308


and exposed portions of etch stop layer


300


(many thousand such plateaus


308


may be arrayed on a single wafer) are then sputtered with MoNiFe to form a first electroplating seed layer


313


about 1000 Å to 1500 Å thick. A first magnetic layer


315


of yoke


303


is then formed by sheet electroplating to a thickness of between 1 μm and 2 μm, and is then defined by ion beam milling. A thin (about 1000 Å thick) amagnetic layer


320


of alumina is then deposited, and a second MoNiFe seed layer


322


is then sputtered, after which a second magnetic layer


327


is formed by sheet electroplating and ion beam milling to be positioned atop amagnetic layer


307


and to have an area slightly less than that of first magnetic layer


315


. The result is a yoke


330


having a flat, recessed middle surface


331


between a pair of raised, flat end surfaces


333


.




In order to provide a planar, insulative surface for the formation of the first coil layer, a first photoresist layer


336


is then deposited to a thickness equal to the height of the recessed surface


331


above the etch stop layer


300


(approximately 4 μm), and patterned to remove those portions of the resist overlaying the yoke


330


and most of the plateaus


308


. A via


338


is also formed in the first resist layer


366


for later connection of the interconnect stud


303


with the first coil layer. The wafer is then heated first to about 100° C. to remove impurities, and then gradually raised in temperature, which causes the remaining photoresist to melt and flow into small spaces left by the patterning and causes sides of the via to slope. After baking at approximately 250° C. for a period of about 5 hours, gradual cooling hardens the photoresist, resulting in a hardbaked condition that offers a hard, insulative layer


336


with a flat surface


331


and


340


for formation of the first coil layer.




Referring now to

FIG. 26

, a second photoresist layer


344


is deposited at this point to provide insulation between the yoke


303


and a first coil layer, and is then developed to remove portions of that layer


344


over the via


338


and the end surfaces


333


. This patterned second resist layer


344


is heated and baked according to a similar process as that described above for the first resist layer


336


to achieve the hardbaked condition. An approximately 500 Å to


1000


Å seed layer


348


of NiFe is then sputtered on the hardbaked resist


344


and interconnect stud


303


, after which is formed, by through plating, a first copper coil layer


350


and an interconnect lead


349


that connects that coil layer


350


and the interconnect stud


303


. Although only a few windings of the first coil layer


350


are shown in this cross-sectional figure for clarity, coil layer


350


has a similar shape and number of windings as that pictured in

FIG. 12

(although coil layer


350


does not cross over). Another via, not shown, is also fashioned at an opposite end of coil layer


350


to provide connection by another interconnect lead, also not shown, for completion of the electrical circuit. A pair of interconnect studs


355


are formed at this point above an inner section of coil layer


350


while the remainder of the coil


350


is covered with photoresist, only one of the studs


355


being shown in this figure.




An alumina layer


360


is then formed on and about the first coil layer


350


, the alumina layer and interconnect studs


355


then being lapped and cleaned to provide a planar surface


363


for further processing. A second coil


366


is formed by through plating atop the alumina layer


360


and interconnect studs


355


on a seed layer, not shown. Another interconnect


368


is formed on an outer coil section for electrical connection with the next coil layer. The magnetic strips


297


are then formed by electroplating, to form a single layer of laminated studs


296


. An alumina isolation layer


370


is then formed on and about the studs


296


and coil


366


, which is then lapped to expose the studs. An etch stop layer


373


of nonconductive SiC is then formed, followed by a third coil layer


377


. Portions of the etch stop layer


373


above the studs are removed, and another alumina layer


380


is formed on and about the third coil layer


377


, which are then lapped flat. Another etch stop layer


383


is then sputtered, on top of which a pedestal


385


is constructed as previously described. Most of the etch stop layer


383


that is not covered by the pedestal


385


is then removed by IBE. The pedestal


385


, any exposed etch stop layer


383


and the exposed alumina layer


380


are then covered with photoresist which is patterned with openings above the studs


396


. An isotropic etch is then performed through the above-stud openings which produces sloping sides


388


of alumina layer


380


. A first


390


and second


393


magnetic layer are then formed on top of the pedestal


385


and alumina layer


380


by window frame plating, with a thin amagnetic alumina layer


395


formed therebetween. The result is a terraced, laminated bottom yoke


399


and a clamshell shaped, laminated magnetic core


400


. The formation of poletips atop the pedestal


385


after lapping to separate the top yoke and the formation of hard material encompassing the poletips proceeds as previously described.




In

FIG. 27

, another embodiment is shown that utilizes a terraced bottom yoke to obviate the need for magnetic studs. The formation of this embodiment proceeds as described immediately above for the previous embodiment which has a single magnetic stud layer core


400


, up to the step of forming a planarized surface


363


atop the top yoke


330


, and so the description of this embodiment having a terraced bottom yoke and no magnetic studs will begin at that stage. Atop the planar surface


363


an etch stop layer


404


of SiC is sputtered. A spiraling coil layer


408


is then formed by through plating on top of the etch stop layer


404


. At this time portions of the etch stop layer


404


atop the raised end sections of top yoke


330


are removed by IBE, although the etch stop layer may alternatively be left intact. Much as before described, copper interconnects


410


are formed by double plating atop exposed outer sections of coil


408


. Another alumina layer


412


is now formed on and about the coil


408


and is lapped flat to expose the interconnect


410


. Another etch stop layer


414


is now formed atop the flat alumina layer


412


, and another layer of coils


418


is then formed atop that etch stop layer


414


and the interconnect which, as before, has been exposed by IBE. Another layer of alumina


420


is then formed on and around coils


418


and is lapped flat, after which an etch stop layer


422


and pedestal


425


is formed, as previously described.




The etch stop covered alumina layers


418


and


412


are then etched in steps to form the terraced profile of those layers shown in this figure. This is achieved by first removing by IBE that portion of etch stop


422


not covered by the pedestal


425


, and then forming a photoresist pattern that has apertures over the raised ends


333


of the top yoke


330


, in order to isotropically etch layer


418


to create sloping sides


428


, with the etching being stopped by layer


414


. Ion beam etching then removes that portion of layer


414


which is not covered by alumina layer


420


, so that another photoresist layer can be patterned with apertures over ends


333


allowing isotropic etching of alumina layer


412


to create sloping sides


430


. That etching is stopped by SiC layer


404


or, for the situation in which layer


404


has been removed to expose ends


333


, the etching is stopped by those ends


333


. A pair of magnetic layers


433


and


435


are then formed by window frame plating, with a thin (1000 Å) alumina layer


438


therebetween, in order to create a laminated bottom yoke


440


. The wavy ribbon of laminated yoke


440


is now ready for the formation of a magnetic pole structure and wear pad, which proceeds as previously described and so will be omitted here for brevity.




In alternative embodiments, not shown, more or fewer coil layers may be formed, essentially by adding or deleting a step of forming a coil layer atop an etch stop layer. For instance, a transducer having only coil layers


350


and


408


may be formed by simply forming the pedestal


425


atop etch stop


414


, instead of forming coil


418


on that layer


414


. On the other hand, a transducer having four coil layers can be formed by constructing an additional coil layer on top of etch stop


422


, and instead forming pedestal


425


on a later formed etch stop layer. One should also note that in other variations the magnetic core may include a wavy or curved bottom yoke while the top yoke is generally planar, although optionally laminated. Also, a curved bottom yoke may be formed on alumina sides that have been sloped, without the employment of multiple etch stop layers, by isotropic etching of each coil-encasing alumina layer through photoresist apertures disposed over ends of the top yoke, with each successive aperture being smaller than the one through which etching of the previous alumina layer occurred.




As shown in

FIG. 28

, non-rectangular chip geometries may be formed by scribe lines


450


, which form in this figure an array of T-shaped chips


455


. The chips


455


each have one MAP


458


and two MIPS


460


disposed in a triangular pattern. After laser scribing is complete, poletips


44


are protected by a photoresist cover while the scribed chips


22


or


455


are exposed to an etchant such as nitric acid (NOH), which selectively dissolves CuRL layer


114


in order to release the formed chips


22


or


455


from the substrate


110


.




Other chip geometries that accommodate a stable spacing of the MAP and MIPS are also possible and have advantages including allowing an increased number of chips per wafer and lowering the mass per chip. In particular, a trapezoidal chip


464


, two of which are shown in

FIG. 29

, has proved to offer increased yield, lower mass and improved mechanical and dynamic performance. A side of the chips


464


facing away from the disk is shown to illustrate the gold interconnect buttons


120


and the leads


466


and


468


that connect those buttons with a pair of connected coils


470


, so that current can flow through the coils via the buttons. Test pads


471


are positioned to allow connection, via the disk-facing side of the chip before formation of the final disk-facing isolation layer, not shown in this figure, with the coils


470


via leads


468


. A pair of chips


464


is shown positioned as they would be on a wafer, which may hold ten thousand or more such chips. MAPs


472


are positioned near lateral extremities of each chip


464


, while scribe lines


474


denote places at which the chips will be separated.





FIG. 30

shows a side of the T-shaped embodiment of the chip


255


that faces away from the disk and is attached to a gimbal structure


500


located near an end of a flexure beam


505


. The attachment of the chip


255


to the gimbal


500


is made by soldering, ultrasonic or thermo-compressive bonding of a conductive paste or metal alloy to the trio of gold buttons


120


on the chip. The flexure beam


505


is formed of a conductive material such as a stainless steel sheet that has been etched or micromachined to create separate conductive paths


510


and


512


that connect to the gold buttons


120


via the gimbal


500


, in order to provide an electrical circuit for the chip


255


as well as tailored mechanical resilience and compliance. The flexure beam


505


also includes a layer of insulative damping material sandwiched between the conductive paths


510


and


512


and another hard but flexible layer, not shown. Also not shown in this figure is a shock absorbing cross bar that is spaced slightly apart from the beam


505


and that keeps the chip


255


from traveling more than a minute amount from the disk surface even under extreme shocks, transferring most of the energy from a shock away from the chip.





FIG. 31

shows a hard disk drive


520


in which the chip


255


operates in substantially continuous sliding contact with a rigid disk


525


on a magnetic recording surface


530


during communication. The beam


285


is connected to a compact, mass balanced rotary actuator


535


that moves the chip


255


between numerous concentric data tracks of the surface


305


while the disk


525


spins in a direction shown by arrow S. Although not shown, a similar chip slides on an opposite magnetic recording surface of the disk


525


, and typically several such disks each having a pair of chips sliding on opposite surfaces are included in a drive system. The drive


520


is designed to achieve substantially continuous sliding contact between the chip


255


and disk


525


at above 5000 RPM and linear velocities of above 10 m/s. This high resolution, continuous contact communication is made possible in part by the extremely small size and non-flying characteristics of the chip, which is constructed entirely from a composite of thin films, as well as the flexible, low load beam


505


and gimbal


500


, which provide damage free conformance between the chip and the disk, and the specific surface characteristics of the disk, which are prepared for such sliding, so that the resulting drive system achieves a synergistic combination optimized to yield a continuously sliding, high density hard disk drive system.



Claims
  • 1. A transducer for a rigid disk drive system, the transducer comprisinga body having a mostly flat disk-facing surface and a protrusion extending from said surface, a magnetic loop contained in said body and extending further in a direction parallel to said surface than in a direction perpendicular to said surface, said loop extending along said surface beyond said protrusion and ending with first and second magnetic pole structures disposed in said protrusion, said pole structures separated by an amagnetic gap and terminating substantially coextensively with said protrusion, and a conductive coil disposed in said body and inductively coupled to said loop, whereby providing an electrical current to said coil induces a magnetic field adjacent to said pole structures for writing a magnetic pattern to a disk.
  • 2. The transducer of claim 1, and further comprising a pair of support legs extending from said surface a similar direction and extent as said protrusion.
  • 3. The transducer of claim 1, wherein said disk-facing surface is formed primarily of at least one thin layer of materials.
  • 4. The transducer of claim 1, wherein a portion of said loop has a magnetic saturation level that is less than that of said pole structures.
  • 5. The transducer of claim 1, wherein said body has a conductive lead connected to said coil and piercing an insulative shell of said body on a side opposite to said disk-facing surface.
  • 6. The transducer of claim 1, wherein said pole structures have a pair of substantially parallel walls adjoining said gap that extend greater than four times as far in a vertical direction as a distance between said walls.
  • 7. The transducer of claim 1, wherein said body is primarily composed of a plurality of adjoining material layers, with a majority of said layers being oriented predominantly parallel to each other and transversely to a layer which is disposed in said gap.
  • 8. A transducer for a rigid disk drive system, the transducer comprisinga plank-shaped body supported by at least one microscopic protrusion, said-body having a length, a width and a thickness, a conductive coil disposed in a part of said body excluding said protrusion, and a magnetic core disposed in said body and inductively coupled to said coil, said core shaped as a loop extending further in a direction of said length than in a direction of said thickness and having ends terminating substantially coextensively with said protrusion and separated by an amagnetic gap, whereby a current flow in said coil produces a magnetic field adjacent to said protrusion.
  • 9. The transducer of claims 8, wherein said ends are encompassed by a durable amagnetic material.
  • 10. The transducer of claim 8, wherein said ends have a pair of substantially parallel walls adjoining said gap that extend greater than four times as far in a vertical direction as said separation between said walls.
  • 11. The transducer of claim 8, wherein said body is primarily made of a composite of thin layers of materials.
  • 12. The transducer of claim 11, wherein said gap is one of said layers and is formed in an orientation generally orthogonal compared to most of said layers.
  • 13. The transducer of claim 8, wherein said body is supported by a plurality of microscopic protrusions.
  • 14. The transducer of claim 8, wherein said body is supported by a trio of microscopic protrusions.
  • 15. The transducer of claim 14, wherein said protrusions are legs.
  • 16. An information storage device comprisinga rigid disk having a surface associated with a magnetic medium layer, a slider having a disk-facing surface and a projection from said disk-facing surface disposed in a mostly sliding relationship with said disk surface, and a transducer disposed in said slider and having a magnetic core and a conductive coil coupled to said core, said core forming a loop extending further in a direction parallel than perpendicular to said disk-facing surface, with closely spaced ends extending into said projection and terminating adjacent to said disk surface.
  • 17. The device of claim 16, and further comprising a pair of spaced apart support legs projecting from said disk-facing surface in a direction substantially similar to that of said projection.
  • 18. The device of claim 16, wherein said loop has a generally symmetric shape that extends furthest in a direction transverse to said projection.
  • 19. The device of claim 16, wherein said slider has a conductive lead connected to said coil, piercing an insulative shell of said slider and protruding away from said disk.
  • 20. The device of claim 16, wherein said ends have a pair of substantially parallel walls separated by an amagnetic gap, said walls extending more than four times as far in a direction substantially normal to said surface as said separation between said walls.
CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of pending U.S. patent application Ser. No. 08/515,140, filed Aug. 15, 1995, and is also a continuation-in-part of pending U.S. patent application Ser. No. 08/338,394, filed Nov. 14, 1994 which is a continuation-in-part of issued U.S. Pat. No. 5,550,691, filed Oct. 27, 1992 as U.S. patent application Ser. No. 07/966,095, which is a continuation-in-part of abandoned U.S. patent application Ser. No. 07/783,509, filed Oct. 28, 1991, which is a continuation-in-part of U.S. patent application Ser. No. 07/632,958, filed Dec. 21, 1990, now U.S. Pat. No. 5,073,242, which is a continuation-in-part of U.S. patent application Ser. No. 07/441,716, filed Nov. 27, 1989, now U.S. Pat. No. 5,041,932. All of the above materials are hereby incorporated by reference into this application.

US Referenced Citations (21)
Number Name Date Kind
3593326 Turner et al. Jul 1971 A
3754104 Piper et al. Aug 1973 A
4698708 Lazzari Oct 1987 A
4731157 Lazzari Mar 1988 A
4819091 Brezoczky et al. Apr 1989 A
4901185 Kubo et al. Feb 1990 A
4949207 Lazzari Aug 1990 A
5041932 Hamilton Aug 1991 A
5065271 Matsuura et al. Nov 1991 A
5111351 Hamilton May 1992 A
5196976 Lazzari Mar 1993 A
5198934 Kubo et al. Mar 1993 A
5278711 Gregory et al. Jan 1994 A
5303096 Keller Apr 1994 A
5305165 Brezoczky et al. Apr 1994 A
5327310 Bischoff et al. Jul 1994 A
5432645 Terunuma et al. Jul 1995 A
5434733 Hesterman et al. Jul 1995 A
5473485 Leung et al. Dec 1995 A
5490028 Ang et al. Feb 1996 A
5539596 Fontana et al. Jul 1996 A
Non-Patent Literature Citations (2)
Entry
Daniel Chapman, “A New Approach To Making Thin Film Head-Slider Devices”, IEEE Transactions on Magnetics, vol. 25, No. 5, Sep. 1989, pp. 3686-3688.*
Autino et al, IEEE Transactions on Magnetics, vol. 28, No. 5, Sep. 1992, Compatibility of Silicon Planar Heads with Conventional Thin Film Heads in Hard Disk Drives.
Continuation in Parts (6)
Number Date Country
Parent 08/515140 Aug 1995 US
Child 08/528890 US
Parent 08/338394 Nov 1994 US
Child 08/515140 US
Parent 07/966095 Oct 1992 US
Child 08/338394 US
Parent 07/783509 Oct 1991 US
Child 07/966095 US
Parent 07/632958 Dec 1990 US
Child 07/783509 US
Parent 07/441716 Nov 1989 US
Child 07/632958 US