Abstract: A method for providing a liftoff process using a single layer resist and chemical mechanical polishing and sensor formed therewith are disclosed. Chemical mechanical polishing is combined with liftoff using only a single resist layer to allow the removal of leftover fencing on the side of a lifted resist pattern.

Abstract: A contact magnetic transfer (CMT) master template is made by first adhering a plastic film to a first surface of a silicon wafer. A resist pattern is then formed on the polyimide film and the polyimide is reactive-ion-etched through the resist to form recesses. The resist is removed and a chemical-mechanical-polishing (CMP) stop layer is deposited over the non-recessed regions of the polyimide, and optionally into the bottoms of the recesses. A layer of magnetic material is then deposited over the polyimide film to fill the recesses. A CMP process is then performed to remove magnetic material above the recesses and above the non-recessed regions and continued until the CMP stop layer is reached. The resulting upper surface of the polyimide film is then a continuous planar film of magnetic islands and regions of CMP stop layer material that function as the nonmagnetic regions of the template.

Abstract: Methods for forming write heads. One method includes forming a mask layer above a pole tip layer; forming a layer of resist above the mask layer; patterning the resist; removing portions of the mask layer not covered by the patterned resist; shaping a pole tip from the pole tip layer; depositing a layer of dielectric material above the pole tip and flux shaping layer, wherein the layer of dielectric material extends about adjacent to the mask layer; depositing a stop layer over the dielectric material, the stop layer abutting the mask layer; and polishing for forming a substantially planar upper surface comprising the mask layer and stop layer. Another method includes depositing a layer of dielectric material at least adjacent the pole tip, wherein the layer of dielectric material extends about adjacent to the mask layer. A further method includes forming dishing in the pole tip.

Abstract: A method for fabricating magnetic side shields for an MR sensor of a magnetic head. Following the deposition of MR sensor layers, a first DLC layer is deposited. Milling mask layers are then deposited, and outer portions of the milling mask layers are removed such that a remaining central portion of the milling mask layers is formed having straight sidewalls and no undercuts. Outer portions of the sensor layers are then removed such that a relatively thick remaining central portion of the milling mask resides above the remaining sensor layers. A thin electrical insulation layer is deposited, followed by the deposition of magnetic side shields. A second DLC layer is deposited and the remaining mask layers are then removed utilizing a chemical mechanical polishing (CMP) liftoff step. Thereafter, the first DLC layer and the second DLC layer are removed and a second magnetic shield layer is then fabricated thereabove.

Abstract: A method and materials to fabricate a trailing shield write pole that resolve the problems of controlling the write gap and preventing damages to the write gap or pole during fabrication of the subsequent structure. This process also introduces a CMP assisted lift-off process to remove re-deposition and fencing (increase yields) and a method to create dishing in the top of the write pole. Moreover, also included in this disclosure are suitable materials that can function as an ion mill transfer layer, CMP layer, and RIEable layer.

Abstract: This invention describes a manufacturable method, including a CMP liftoff process, for removing masking materials after ion milling for fabricating the write pole of a magnetic head. Significant parameters for the CMP assisted liftoff process include the thickness of the remaining mask materials after the write pole ion milling for effective CMP assisted liftoff, the thickness of the dielectric fill material deposited to protect the write pole during the CMP liftoff step, and the type of CMP slurry, polishing pad and the polishing conditions that are required to yield satisfactory results.

Abstract: A method is described which uses a CMP slurry with an abrasive of spherical particles to lift-off photoresist used in the patterning of the sensor for a magnetic transducer. The spherical particles, preferably less than 0.015 microns, are preferably silica, alumina, titania or zirconia with colloidal silica being preferred. An alternative method of fabricating a CPP sensor structure according to the invention deposits a dielectric or CMP resistant metal over the hard bias structure. The CMP-resistant metal is preferably selected from the group consisting of rhodium, chromium, vanadium and platinum. A CMP resistant mask deposited over the dielectric or CMP-resistant metal can include an optional adhesion layer such as tantalum followed by a DLC layer. The CMP-assisted lift-off of the photoresist and the excess materials is executed at this point. The photoresist used to protect the selected area of the sensor structure is lifted-off using the slurry.

Abstract: A contact magnetic transfer (CMT) master template has a flexible plastic film with a planarized top or upper surface containing magnetic islands separated from one another by nonmagnetic regions. The flexible plastic film is secured at its perimeter to a silicon annulus that provides rigid support at the perimeter of the film. The plastic film is preferably polyimide that has recesses filled with the magnetic material that form the pattern of magnetic islands. The upper surfaces of the islands and the upper surfaces of the nonmagnetic regions form a continuous planar surface. The nonmagnetic regions are formed of chemical-mechanical-polishing (CMP) stop layer material that remains after a CMP process has planarized the upper surface of the plastic film.

Abstract: A contact magnetic transfer (CMT) master template is made by first adhering a plastic film to a first surface of a silicon wafer. A resist pattern is then formed on the polyimide film and the polyimide is reactive-ion-etched through the resist to form recesses. The resist is removed and a chemical-mechanical-polishing (CMP) stop layer is deposited over the non-recessed regions of the polyimide, and optionally into the bottoms of the recesses. A layer of magnetic material is then deposited over the polyimide film to fill the recesses. A CMP process is then performed to remove magnetic material above the recesses and above the non-recessed regions and continued until the CMP stop layer is reached. The resulting upper surface of the polyimide film is then a continuous planar film of magnetic islands and regions of CMP stop layer material that function as the nonmagnetic regions of the template.

Abstract: The method of making a magnetic head assembly includes forming a second pole piece layer that is recessed from a head surface, forming a reactive ion etchable (RIEable) pole tip forming layer on the second pole piece layer, forming an adhesion/stop layer of tantalum (Ta) on the pole tip forming layer, forming a photoresist mask on the adhesion/stop layer with an opening for patterning the adhesion/stop layer and the pole tip forming layer with another opening, reactive ion etching (RIE) through the opening to form the other opening, forming the second pole piece pole tip in the other opening with a top which is above a top of the adhesion/stop layer and chemical mechanical polishing (CMP) the top of the second pole piece pole tip until the CMP contacts the adhesion/stop layer. The invention also includes the magnetic head made by such a process.

Abstract: A method for constructing a magnetoresistive sensor using an etch mask that is resistant to the material removal process used to define the sensor width and stripe height. The method may include the use of a Ta etch mask formed under a photoresist mask, and the use of an ion milling process to define the sensor. The etch mask remains substantially intact after performing the ion milling and therefore is readily removed by a later CMP process. The etch mask layer is also very resistant to high temperatures such as those used in a desired atomic layer deposition of alumina, which is used to deposit conformal layers of alumina around the sensor.

Abstract: A read head has a bottom lead made of material that is relatively polish resistant and a top lead layer that polishes down more easily than the bottom layer. With this structure, when the layers are deposited and then polished down, the top layer recesses away from the sensor (and bottom lead layer) in a controlled fashion, providing an acceptable lead structure that reduces the mismatch between the read head physical read width and magnetic read width.

Abstract: The method of making a magnetic head assembly includes forming a second pole piece layer that is recessed from a head surface, forming a reactive ion etchable (RIEable) pole tip forming layer on the second pole piece layer, forming an adhesion/stop layer of tantalum (Ta) on the pole tip forming layer, forming a photoresist mask on the adhesion/stop layer with an opening for patterning the adhesion/stop layer and the pole tip forming layer with another opening, reactive ion etching (RIE) through the opening to form the other opening, forming the second pole piece pole tip in the other opening with a top which is above a top of the adhesion/stop layer and chemical mechanical polishing (CMP) the top of the second pole piece pole tip until the CMP contacts the adhesion/stop layer. The invention also includes the magnetic head made by such a process.

Abstract: A method for forming a read transducer by ion milling and chemical mechanical polishing to eliminate nonuniformity near the MR sensor is disclosed. The resist mask is eliminated in the read transducer formation process so that the thickness of the layers near the read transducer has a uniform thickness.

Abstract: A method is described which uses a CMP slurry with an abrasive of spherical particles to lift-off photoresist used in the patterning of the sensor for a magnetic transducer. The spherical particles, preferably less than 0.015 microns, are preferably silica, alumina, titania or zirconia with colloidal silica being preferred. An alternative method of fabricating a CPP sensor structure according to the invention deposits a dielectric or CMP resistant metal over the hard bias structure. The CMP-resistant metal is preferably selected from the group consisting of rhodium, chromium, vanadium and platinum. A CMP resistant mask deposited over the dielectric or CMP-resistant metal can include an optional adhesion layer such as tantalum followed by a DLC layer. The CMP-assisted lift-off of the photoresist and the excess materials is executed at this point. The photoresist used to protect the selected area of the sensor structure is lifted-off using the slurry.

Abstract: A method is described which uses a CMP resistant metal layer to replace the upper dielectric layer in the track width definition phase of a TMR or CPP spin valve magnetic head. The metal which is selected to be resistant to the CMP process can be rhodium (Rh), platinum (Pt), chromium (Cr), vanadium (V), etc. The additional CMP resistance of the refill layer structure provides a much larger processing window which results in higher yields. A CPP head according to the invention has a metal layer according to the invention above the hard bias structures on the sides of the sensor which define the track width.

Abstract: A method is described which uses a CMP slurry with an abrasive of spherical particles to lift-off photoresist used in the patterning of the sensor for a magnetic transducer. The spherical particles are preferably silica, alumina, titania or zirconia with colloidal silica being preferred. The size of the particle is preferably less than 0.015 microns. The pH is preferably alkaline and even more preferably with a pH of about 10-11. In a method according to the invention a CPP sensor structure width or height is defined according to the prior art by removing excess sensor material at opposite sides of the sensor structure to form voids to define the track width or stripe height. The photoresist used to protect the selected area of the sensor structure is lifted-off using the slurry.

Abstract: The magnetic head includes a second magnetic shield that is fabricated in a deposition process. The present invention therefore does not require the deposition of the electrically conductive seed layer. In a preferred embodiment, the deposited second magnetic shield is comprised of cobalt zirconium tantalum (CZT). Because the CZT material is relatively soft, it is preferably deposited within an opening formed in a relatively hard RIEable material such as Ta2O5, SiO2, Si3N3, and SiOxNy, such that a subsequent chemical mechanical polishing (CMP) step can be conducted down to the surface of the relatively hard layer.

Abstract: A method and apparatus for defining leading edge taper of a write pole tip is disclosed. The fabrication process uses reactive ion etching to fabricate LET with tight control of the placement of LET's edge and to achieve higher angle for providing a higher effective write field at the pole tip while minimizing ATI for high-density perpendicular recording. The placement of a resist's edge is used to define the LET's edge and a CMP process is used to provide a planar surface for the fabrication of the write pole.

Abstract: A read head has a bottom lead made of material that is relatively polish resistant and a top lead layer that polishes down more easily than the bottom layer. With this structure, when the layers are deposited and then polished down, the top layer recesses away from the sensor (and bottom lead layer) in a controlled fashion, providing an acceptable lead structure that reduces the mismatch between the read head physical read width and magnetic read width.