Patent Application
20110007427
To increase the storage capacity of a magnetic data storage device such as, for example, a hard disc drive (HDD), the size of the magnetically oriented domains (bits) on the magnetic storage medium in the drive (the data discs) is continually being made smaller to produce higher data densities. This continued growth in magnetic recording areal density in the HDD industry requires a corresponding continuous reduction in the physical dimensions of the components in the HDD, particularly the read/write heads.
For example, the magnetoresistive (MR) sensor in the read/write heads includes shields made of materials having high magnetic permeability, which protect the sensor from stray magnetic fields originating from adjacent magnetic bits on the data storage medium. The spacing between the shields (referred to herein as the shield-to-shield spacing) can be made smaller to more effectively screen the flux from adjacent bits and provide a magnetic data storage device with higher linear recording density (Bit Per Inch (BPI)).
In one embodiment, the present disclosure is directed to a magnetic sensor assembly including first and second shields, and a sensor stack between the first and second shields, wherein the sensor stack includes a seed layer adjacent the first shield, a cap layer adjacent the second shield, and a magnetic sensor between the seed layer and the cap layer. At least one of the seed layer and the cap layer has a synthetic antiferromagnetic structure.
In another embodiment, the present disclosure is directed to a magnetic sensor assembly including a first shield layer and a first seed layer adjacent the first shield layer, wherein the first seed layer has a synthetic antiferromagnetic structure. A sensor stack is adjacent the seed layer, wherein the sensor stack includes a magnetic sensor. A first cap layer is adjacent the sensor stack, wherein the first cap layer includes a synthetic antiferromagnetic structure. A second shield layer is adjacent the first cap layer.
In yet another embodiment, the present disclosure is directed to a read/write head for a data storage device, wherein the head includes a magnetic sensor assembly. The magnetic sensor assembly includes a first shield layer and a first seed layer adjacent the first shield layer, wherein the first seed layer includes a synthetic antiferromagnetic structure; a sensor stack adjacent the seed layer, wherein the sensor stack includes a magnetic sensor; a first cap layer adjacent the sensor stack, wherein the first cap layer includes a synthetic antiferromagnetic structure; and a second shield layer adjacent the first cap layer.
The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. These and various other features and advantages will be apparent from a reading of the following detailed description.
In the drawings, like symbols indicate like elements. The drawings are not to scale.
A magnetic read/write head for use in a magnetic data storage device can be made by a process in which a layer of diamond like carbon (DLC) is applied on a tunneling magnetoresistive (TMR) or a current perpendicular-to-the-plane (CPP) sensor stack. A photoresistive material can be applied on the DLC layer, and portions of the photoresist and the sensor stack are then ion milled to provide a sensor with desired dimensions. A layer of an insulating material and a layer of a hard magnetic material are then applied over the ion milled structure, and chemical mechanical polishing (CMP) is utilized to abrade away portions of the hard magnetic material, the insulating material, and the photoresist down to the DLC layer. The DLC layer is then removed, and top electrode and shield layers are applied to form the finished read/write head.
To further decrease shield-shield spacing to a level below about 40 nanometers (nm), the thicknesses of the layers in the sensor stack should preferably be carefully controlled. The CMP steps in the process described above introduce undesirable variations in the thicknesses of the sensor layers, which can reduce the reliability of sensors having a shield-to-shield spacing of less than 40 nm.
To reduce sensor layer thickness variations caused by CMP, a magnetic cap and/or seed layer can be applied on the sensor stack adjacent to the sensor shields. These additional magnetic layers can act as sacrificial layers during the CMP process steps, and portions thereof remaining following CMP steps eventually become part of the sensor shields. However, the magnetic flux resulting from the shape anisotropy of these additional magnetic layers can apply a magnetic torque on the other layers in the sensor stack, which can cause undesirable signal losses. This unwanted magnetic torque can also destabilize layers in the sensor stack during manufacture, and may cause undesirable sensor instability.
To reduce CMP thickness variations without introducing undesirable additional magnetic torque, the present disclosure is directed to a sensor stack in which the cap and/or seed layers adjacent the shields are SAF (synthetic antiferromagnetic) structures. Unlike the sacrificial magnetic layers described above, the SAF structures lack shape anisotropy, and their balanced structure does not apply an undesirable torque on the other layers of the sensor stack. The SAF cap and seed layers reduce thickness variations caused by CMP steps, and sensor stacks with the SAF layers have reduced shield-to-shield spacing while retaining excellent signal strength.
Referring again to
The read head 200 includes a first shield layer 202 and a second shield layer 203, a tunneling magneto-resistive sensor 218 and two hard magnets 204, 205. The first and second shield layers 202, 203, which are made of a material having high magnetic permeability, reduce or substantially block extraneous magnetic fields, such as, for example, those from adjacent bits on data discs from impacting the sensor 218, thus improving the performance of the sensor 218. Ideally, the first and second shield layers 202, 203 permit magnetic fields from only the bit directly under sensor 218 to affect the sensor, and thus be read. Thus, as the physical size of bits continues to decrease, the shield-to-shield spacing should also be decreased.
The sensor 218 includes a plurality of layers, including an antiferromagnetic seed layer 214, a pinned layer 212, a reference layer 211, a tunneling barrier layer 210, a free layer 208 and a cap layer 206. The antiferromagnetic layer 214 is electrically coupled to a first electrode 221, and the cap layer 206 is electrically coupled to a second electrode 220. The pinned layer 212 is formed on and exchange coupled to the antiferromagnetic layer 214. The exchange coupling fixes the magnetic moment of the pinned layer 212 in a known orientation. Likewise, the magnetic moment of the pinned layer 212 induces a substantially antiparallel magnetic field in the reference layer 211. Together, the pinned layer 212 and the reference layer 211 form a synthetic antiferromagnet 213. The magnetic moments of each of the pinned layer 212 and the reference layer 211 are not allowed to rotate under magnetic fields in the range of interest (e.g., magnetic fields generated by the bits of data stored on the data discs). The magnetic moments of the reference layer 211 and the pinned layer 212 are generally oriented normal to the plane of
The sensor also includes a free layer 208, which is not exchange coupled to an antiferromagnet. Thus, the magnetic moment of the free layer 208 is free to rotate under the influence of an applied magnetic field in the range of interest.
The read head 200 further includes a pair of bias magnets 204 and 205, which produce a magnetic field that biases the free layer 208 with a magnetic moment parallel to the plane of the figure and generally oriented horizontally, as indicated by arrow 226. This bias prevents the magnetic moment of the free layer 208 from drifting due to, for example, thermal energy, which may introduce noise into the data sensed by the read head 200. The bias is sufficiently small, however, that the magnetic moment of the free layer 208 can change in response to an applied magnetic field, such as a magnetic field of a data bit stored on the data discs. The sensor 218 and electrodes 220, 221 are separated and electrically isolated from the bias magnets 204, 205 by insulating materials 222, 223, respectively.
The tunneling barrier layer 210 separates the free layer 208 and the reference layer 211. The tunneling barrier layer 210 is sufficiently thin that quantum mechanical electron tunneling occurs between the reference layer 211 and the free layer 208. The electron tunneling is electron-spin dependent, making the magnetic response of the sensor 218 a function of the relative orientations and spin polarizations of the reference layer 211 and the free layer 208. The highest probability of electron tunneling occurs when the magnetic moments of the reference layer 211 and the free layer 208 are parallel, and the lowest probability of electron tunneling occurs when the magnetic moments of the reference layer 211 and the free layer 208 are antiparallel. Accordingly, the electrical resistance of the sensor 218 changes in response to an applied magnetic field. The data bits on the data discs in the disc drive are magnetized in a direction normal to the plane of
To increase the storage capacity of a magnetic data storage device such as a disc drive, the size of the magnetically oriented domains (bits) on the data discs is continually being made smaller to produce higher data densities. Accordingly, the size of read head 200 must be made smaller, and particularly, the shield to shield spacing must be decreased, so that the sensor 218 is substantially isolated from the magnetic fields of adjacent bits on data discs 108.
The magnetic materials used in the seed layer 315 and the second cap layer 350 have a magnetic moment parallel to the plane of the figure and generally oriented horizontally, as indicated by arrows 316 and 351, respectively. Due to shape anisotropy, magnetic flux from the magnetic seed layer 315 applies a magnetic torque along lines 316A and 316B, respectively, on the AFM layer 314, as well as to the synthetic antiferromagnet 313 formed by the pinned layer 312 and the reference layer 311. This torque can destabilize the AFM layer 314 as the TMR stack 318 is annealed during manufacture, and can also destabilize the synthetic antiferromagnet 313. The magnetic flux from the magnetic second cap layer 350 applies a magnetic torque along line 351A to the free layer 308. This causes the magnetic moment of the free layer 308 to align anti-parallel to the direction of the media field, which is opposite to the signal detection scheme and can result in undesirable signal losses.
To reduce SSeff without introducing undesirable additional magnetic torque into the magnetic sensor assembly,
The TMR stack 418 includes a non-magnetic seed layer 417, an AFM layer 414, a pinned layer 412, a reference layer 411, a tunneling barrier layer 410, a free layer 408 and a first cap layer 406 made of a non-magnetic material such as, for example, Ta.
The non-magnetic seed layer 417 can be made of a wide variety of materials such as, for example, Ta, Ru, Cr or combinations thereof. Suitable materials for the first cap layer 406 include, for example, Ta, Ru, Cr or combinations thereof.
The stack 418 further includes a second cap layer 460 with a synthetic antiferromagnetic structure and a thickness tcap. The second cap layer 460 includes a layer of a first shield material 462 having a magnetic moment generally aligned along a direction indicated by the arrow 462A, as well as a layer of a second shield material 464 having a magnetic moment generally aligned along a direction indicated by the arrow 464A. The first and second materials may be the same or different. The first and second shield materials 462, 464 may be the same as the materials used to make the shield 403 (e.g. NiFe), or may be selected from different materials such as, for example, NiFex, FeCo, Fe, Ni or a combination thereof. In some embodiments, an antiferromagnetic (AFM) coupling layer 463 resides between the first shield material 462 and the second shield material 464. Suitable materials for the AFM coupling layer 463 include, but are not limited to, Ru.
When the second cap layer 460 is made of a synthetic antiferromagnetic material, the effective shield-to-shield spacing (SSeff) of the TMR stack 418 is reduced from the physical shield-to-shield spacing SSp by the thickness tcap of the cap layer 460.
In some embodiments, the second cap layer 460 has a thickness of between about 10 Å and about 1,000 Å. The thickness of the second cap layer 460 should preferably be small but sufficient to tolerate CMP variations, and the thickness is typically between about 2 nm and about 10 nm.
However, unlike the magnetic second cap layer 350 shown in
To reduce SSeff without introducing undesirable additional magnetic torque into the magnetic sensor assembly,
The TMR stack 518 further includes a seed layer 570 with a synthetic antiferromagnetic structure and a thickness tseed. The seed layer 570 includes a layer of a first shield material 572 having a magnetic moment generally aligned along a direction indicated by the arrow 572A, as well as a layer of a second shield material 574 having a magnetic moment generally aligned along a direction indicated by the arrow 574A. The first and second shield materials making up the layers 572, 574 may be the same or different. The first and second materials in the layers 572, 574 may be the same as the materials used to make the shields 502 or 503 (e.g. NiFe), or may be selected from different materials such as, for example, NiFex, FeCo, Fe, Ni or a combination thereof. In some embodiments, an AFM coupling layer 573 resides between the first shield material 572 and the second shield material 574. Suitable materials for the AFM coupling layer 573 include, but are not limited to, Ru.
When the seed layer 570 is made of a synthetic antiferromagnetic material, the effective shield-to-shield spacing (SSeff) of the TMR stack 518 is reduced from the physical shield-to-shield spacing SSp by the thickness tseed of the seed layer 570. In some embodiments, the seed layer 570 has a thickness of between about 10 Å and about 1,000 Å. However, unlike the magnetic seed layer 315 shown in
In yet another embodiment shown in
The TMR stack 618 further includes a seed layer 670 with a synthetic antiferromagnetic structure and a thickness tseed. The seed layer 670 includes a layer of a first shield material 672 having a magnetic moment generally aligned along a direction indicated by the arrow 672A, as well as a layer of a second shield material 674 having a magnetic moment generally aligned along a direction indicated by the arrow 674A. The first and second shield materials making up the layers 672, 674 may be the same or different. The first and second shield materials in the layers 672, 674 may be the same as the materials used to make the shield 602 (e.g. NiFe), or may be selected from different materials such as, for example, NiFex, FeCo, Fe, Ni or a combination thereof. In some embodiments, an AFM coupling layer 673 resides between the first shield material 672 and the second shield material 674. Suitable materials for the AFM coupling layer 673 include, but are not limited to, Ru.
When the seed layer 670 is made of a synthetic antiferromagnetic material, the effective shield-to-shield spacing (SSeff) of the TMR stack 618 is reduced from the physical shield-to-shield spacing SSp by the thickness tseed of the seed layer 670. In addition, when the bottom synthetic antiferromagnetic seed layer 670 is present, the non-magnetic seed layer 614 can optionally be removed to further reduce shield-to-shield spacing. In some embodiments, the seed layer 670 has a thickness of between about 10 Å and about 1,000 Å. The antiferromagnetic seed layer 670 has a balanced magnetic structure, so the magnetic flux of the layer 670 is applied along the direction shown by arrow 670A. Thus, while reducing the SSeff, the layer 670 applies additional unwanted magnetic torque to neither the AFM layer 614 nor the synthetic antiferromagnet 613, which preserves the stability of the TMR stack 618.
The TMR stack 618 further includes a second cap layer 660 with a synthetic antiferromagnetic structure and a thickness tcap. The second cap layer 660 includes a layer of a first shield material 662 having a magnetic moment generally aligned along a direction indicated by the arrow 662A, as well as a layer of a second shield material 664 having a magnetic moment generally aligned along a direction indicated by the arrow 664A. The first and second materials may be the same or different. The first and second materials may be the same as the materials used to make the shield 603 (e.g. NiFe), or may be selected from different materials such as, for example, NiFex, FeCo, Fe, Ni or a combination thereof. In some embodiments, an AFM coupling layer 663 resides between the first shield material 662 and the second shield material 664. Suitable materials for the antiferromagnetic (AFM) coupling layer 663 include, but are not limited to, Ru.
When the second cap layer 660 is made of a synthetic antiferromagnetic material, the effective shield-to-shield spacing (SSeff) of the TMR stack 618 is reduced from the physical shield-to-shield spacing SSp by the thickness tcap of the cap layer 660. In some embodiments, the second cap layer 660 has a thickness of between about 10 Å and about 1,000 Å. The antiferromagnetic second cap layer 660 has a balanced magnetic structure, so the magnetic flux of the layer 660 is applied along the direction shown by arrow 660A. Thus, while reducing the SSeff, the layer 660 applies no additional unwanted magnetic torque to the free layer 608, and preserves the signal strength of the TMR stack 618.
Various embodiments of the invention have been described. The implementations described above and other implementations are within the scope of the following claims.
