JP5542372B2 - Perpendicular magnetic recording medium - Google Patents

Description

  The present invention relates to a perpendicular magnetic recording medium mounted on a magnetic disk device such as an HDD (Hard Disk Drive) of a perpendicular magnetic recording system.

  Various information recording techniques have been developed with the recent increase in information processing capacity. In particular, the surface recording density of an HDD (hard disk drive) using magnetic recording technology continues to increase at an annual rate of about 100%. Recently, an information recording capacity exceeding 250 Gbytes has been required for a 2.5 inch diameter magnetic disk used for HDDs and the like. In order to meet such a requirement, one square inch is required. It is required to realize an information recording density exceeding 400 Gbits per unit. In order to achieve a high recording density in a magnetic disk used for an HDD or the like, it is necessary to refine the magnetic crystal particles constituting the magnetic recording layer for recording information signals and to reduce the layer thickness. It was. However, in the case of magnetic disks of the in-plane magnetic recording method (also called longitudinal magnetic recording method or horizontal magnetic recording method) that have been commercialized conventionally, as a result of the progress of miniaturization of magnetic crystal grains, superparamagnetic phenomenon The thermal stability of the recording signal is impaired, the recording signal disappears, and a thermal fluctuation phenomenon occurs, which has been an impediment to increasing the recording density of the magnetic disk.

  In order to solve this obstruction factor, a magnetic disk for perpendicular magnetic recording has recently been proposed (see, for example, Patent Documents 1 to 3). In the case of the perpendicular magnetic recording system, unlike the case of the in-plane magnetic recording system, the easy axis of magnetization of the magnetic recording layer is adjusted to be oriented in the direction perpendicular to the substrate surface. The perpendicular magnetic recording method can suppress the thermal fluctuation phenomenon as compared with the in-plane recording method, and is suitable for increasing the recording density.

  For example, Patent Document 1 discloses a technique related to a perpendicular magnetic recording medium in which an underlayer, a Co-based perpendicular magnetic recording layer, and a protective layer are formed in this order on a substrate. Patent Documents 2 and 3 propose a CGC (Coupled Granular and Continuous) medium provided with a granular layer (Granular layer) and a continuous film layer (Continuous layer).

  In the CGC medium described in Patent Documents 2 and 3, as shown in FIG. 2, a main recording layer is formed on an intermediate layer (3) such as a soft magnetic layer, an orientation control layer, an underlayer, and a miniaturization promoting layer. The magnetic crystal grains (Co Grain) (11) exhibiting perpendicular magnetic anisotropy and the magnetic crystal grains (Co Grain) (11) are magnetically separated from each other at the grain boundary. A granular layer (magnetic layer) (1) composed of a grain boundary portion (Oxide) (12) composed of a non-magnetic substance such as an oxide is formed to substantially influence the influence of the magnetization transition region in the main recording layer. By eliminating them, the magnetization transition region noise is reduced. Further, a continuous layer having a magnetic coupling force in a direction parallel to the main surface of the substrate is used as the auxiliary recording layer 2 on the granular layer (magnetic layer) (1). 2) and the granular layer (magnetic layer) (1) are exchange-coupled magnetically, and the magnetization of the continuous layer (auxiliary recording layer) (2) is pinned by the magnetization of the granular layer (magnetic layer) (1). ) To improve the thermal stability of the recorded signal. Thereby, in the CGC medium, the recording density can be increased.

JP 2002-92865 A US Pat. No. 6,468,670 JP 2008-84432 A

  What is required as characteristics of the media used in the HDD is that the recorded signal has a good S / N ratio, good thermal stability, easy recording, and the like. Among these, in order to improve the SN ratio, it is necessary to reduce the particle size of the magnetic particles constituting the magnetic recording layer. However, if the magnetic particles are made smaller, the signal becomes thermally unstable. In order to stabilize the signal thermally, it is necessary to increase the perpendicular magnetic anisotropy energy (Ku), but if the perpendicular magnetic anisotropy energy (Ku) is increased too much, information is recorded by the magnetic head. Can not be.

  In a CGC medium, a magneto-optical characteristic ((a) is obtained by laminating a granular magnetic recording layer and an auxiliary recording layer, controlling exchange coupling between magnetic particles in the granular magnetic recording layer and the auxiliary recording layer, and adjusting the exchange interaction. SN ratio), recording characteristics (ease of recording), and thermal stability can be controlled.

  However, according to studies by the present inventors, in the CGC medium disclosed in Patent Document 2, since the auxiliary recording layer is a continuous film, the exchange interaction between magnetic grains in the auxiliary recording layer is strong. Moreover, the dispersion of the magnetic particles was large, and it was thought that this might cause noise generation.

  The present invention solves the problems of such a CGC recording medium, and an object of the present invention is to provide a perpendicular magnetic recording medium capable of high density recording with an improved S / N ratio.

The present inventors have noted that the auxiliary recording layer used in the CGC medium is a continuous layer that does not contain an oxide. If the auxiliary recording layer is a continuous layer, the exchange interaction between the magnetic grains in the auxiliary recording layer is strong, and the dispersion of the magnetic grains is large, which is considered to cause noise.
Therefore, as a result of trying to add, for example, silver (Ag) which is insoluble in cobalt (Co) as a main component showing perpendicular magnetic anisotropy in the auxiliary recording layer to the auxiliary recording layer. It has been found that a perpendicular magnetic recording medium capable of high density recording with improved magnetic characteristics (S / N ratio) and improved noise and bit error rate can be obtained.
In order to solve the above problems, the present invention has the following configuration.

(Configuration 1)
A perpendicular magnetic recording medium comprising at least a granular magnetic recording layer and an auxiliary recording layer having magnetic particles exhibiting perpendicular magnetic anisotropy exchange-coupled to magnetic crystal grains in the granular recording layer, wherein the auxiliary recording layer Is a perpendicular magnetic recording medium characterized in that it contains a non-solid solution that is insoluble in the magnetic particles constituting the auxiliary recording layer.

(Configuration 2)
The auxiliary recording layer is made of a Co-based alloy containing cobalt (Co) as a main component of magnetic particles exhibiting perpendicular magnetic anisotropy, and the non-solid substance is a non-solid solution with respect to cobalt (Co). The structure 1 is characterized in that at least one of certain silver (Ag) or Ta, W, or C is selected, and the concentration of the non-solid solution substance is in a range of 0.1 at% or more and 10 at%. A perpendicular magnetic recording medium.

(Configuration 3)
The granular magnetic recording layer has a granular crystal structure having magnetic crystal grains mainly composed of cobalt (Co) and a grain boundary portion made of a nonmagnetic material that magnetically separates the magnetic crystal grains at the grain boundaries of the magnetic crystal grains. The perpendicular magnetic recording medium according to Configuration 1 or 2, further comprising a ferromagnetic layer.

(Configuration 4)
An exchange coupling control layer made of a nonmagnetic material that controls exchange coupling between the granular magnetic recording layer and the auxiliary recording layer is interposed between the granular magnetic recording layer and the auxiliary recording layer. 4. The perpendicular magnetic recording medium according to any one of configurations 1 to 3, wherein:

  According to the present invention, the auxiliary recording layer contains a non-solid solution substance that is insoluble with the magnetic particles constituting the auxiliary recording layer, thereby adjusting the exchange interaction between the magnetic particles of the auxiliary recording layer. Also, as a result of the improved dispersion of the magnetic particles, the recording characteristics (easy to record) of the obtained perpendicular magnetic recording medium and the SN ratio of the recorded signal can be improved.

1 is a schematic longitudinal sectional view of a perpendicular magnetic recording medium according to an embodiment of the present invention. It is a figure which illustrates typically the role of the continuous layer (auxiliary recording layer) in a general CGC medium. It is a figure which shows the relationship between magnetic execution width (MWw) and OW2 which is a parameter showing the write performance of a signal. It is a figure which shows the relationship between the bit error rate (bER) with respect to a magnetic execution width (MWw), and a magnetostatic characteristic (SN). It is a figure explaining a corrosion test result. It is a figure explaining a pin-on test result.

The perpendicular magnetic recording medium according to the present invention includes at least a granular magnetic recording layer and auxiliary grains having perpendicular magnetic anisotropy that exchange-couples with the magnetic crystal grains in the granular recording layer, as in Configuration 1. A perpendicular magnetic recording medium including a recording layer, wherein the auxiliary recording layer includes a non-solid solution material that is insoluble in the magnetic particles constituting the auxiliary recording layer.
Here, the auxiliary recording layer is preferably made of a Co-based alloy in which, for example, silver (Ag) that is insoluble in cobalt (Co) is selected as the insoluble material.
The granular magnetic recording layer has a granular structure having magnetic crystal grains mainly composed of cobalt (Co) and a grain boundary portion made of a nonmagnetic material that magnetically separates the magnetic crystal grains at the grain boundaries of the magnetic crystal grains. The ferromagnetic layer is preferably included.

  Exemplary embodiments of the present invention will be described below in detail with reference to the accompanying drawings. In the present specification and drawings, components having substantially the same functional configuration are denoted by the same reference numerals, and redundant description is omitted. Note that dimensions, materials, and other specific numerical values shown in the following examples are merely examples for facilitating the understanding of the invention, and do not limit the present invention unless otherwise specified.

FIG. 1 is a schematic longitudinal sectional view showing the structure of a perpendicular magnetic recording medium according to an embodiment of the present invention. According to the embodiment shown in FIG. 1, a perpendicular magnetic recording medium 100 according to the present invention is roughly composed of a disk substrate 110, an adhesion layer 112, a soft magnetic layer 114, an orientation control layer 116, an underlayer 118, and a miniaturization promoting layer 120. , A magnetic recording layer 122, a continuous layer (auxiliary recording layer) 124, a medium protective layer 126, and a lubricating layer 128.
Here, the soft magnetic layer 114 includes a first soft magnetic layer 114a, a spacer layer 114b, and a second soft magnetic layer 114c, which are sequentially stacked.
The underlayer 118 includes a first underlayer 118a and a second underlayer 118b. The magnetic recording layer 122 includes a first magnetic recording layer 122a and a second magnetic recording layer 122b.

  The disk substrate 110 is preferably non-magnetic glass. Specific examples include aluminosilicate glass, aluminoborosilicate glass, soda lime glass, and aluminosilicate glass is particularly preferable. Since the aluminosilicate glass is smooth and has high rigidity, the magnetic spacing, particularly the flying height of the magnetic head, can be more stably reduced. Aluminosilicate glass can obtain high rigidity and strength by chemical strengthening. When the soft magnetic layer 114 is amorphous, the disk substrate 110 is also preferably made of amorphous glass.

In the perpendicular magnetic recording medium 100 according to the present invention, the adhesive layer 112 to the medium protective layer 126 are sequentially formed on the disk substrate 110, and then the lubricating layer 128 is formed by a dip coating method. It is done.
Here, the adhesive layer 112 to the continuous layer 124 are preferably formed by a sputtering apparatus as a vacuum film forming apparatus, and particularly preferably formed by using a DC magnetron sputtering apparatus because uniform film formation is possible. The medium protective layer 126 is preferably formed by a CVD (Chemical Vapor Deposition) apparatus as a vacuum film forming apparatus. Note that it is also preferable to use an in-line film forming method in terms of high mass productivity.

Below, the structure and manufacturing method of each layer are demonstrated.
The adhesion layer 112 improves the adhesion between the disk substrate and the film laminated thereon (in this embodiment, the soft magnetic layer 114 or the first soft magnetic layer 114a), and is suitable for implementing the present invention. Is adopted. The material of the adhesion layer 112 is not particularly limited, but when non-magnetic glass is selected as the disk substrate 110, for example, a Ti-containing material can be exemplified. From the practical viewpoint, the thickness of the adhesion layer is preferably 1 nm to 50 nm.

  In a preferred embodiment, for example, the adhesion layer 112 is formed using a Ti alloy target so as to be a 10 nm Ti alloy layer. By forming the adhesion layer 112, the adhesion between the disk substrate 110 and the soft magnetic layer 114 can be improved, so that the soft magnetic layer 114 can be prevented from peeling off. As a material of the adhesion layer 112, for example, a CrTi alloy can be used.

  The soft magnetic layer 114 is a layer for suitably adjusting the magnetic circuit of the magnetic recording layer 122, and is used in a preferred embodiment of the present invention. The soft magnetic layer preferably has a magnetic property of 0.01 to 80 oersted, preferably 0.01 to 50 oersted, for example, in terms of coercive force (Hc). The saturation magnetic flux density (Bs) preferably has a magnetic characteristic of 500 emu / cc to 1920 emu / cc. The soft magnetic layer 114 may be a single layer or a multilayer. The total thickness of the soft magnetic layer is 20 nm to 120 nm, preferably 20 nm to 100 nm.

The soft magnetic layer and the material are not particularly limited as long as they are made of a magnetic material, and examples thereof include Fe-based and Co-based materials. For example, Fe-based soft magnetic materials such as FeTaC-based alloys, FeTaN-based alloys, FeNi-based alloys, FeCoB-based alloys and FeCo-based alloys, Co-based soft magnetic materials such as CoTaZr-based alloys and CoNbZr-based alloys, or FeCo-based alloy soft magnetic materials Materials and the like can be used.
Here, in the soft magnetic layer 114 according to this embodiment, the nonmagnetic spacer layer 114b is interposed between the soft magnetic layer as a multilayer of the first soft magnetic layer 114a and the second soft magnetic layer 114c. And AFC (Antiferro-magnetic exchange coupling). Thereby, the magnetization direction of the soft magnetic layer 114 can be aligned along the magnetic path (magnetic circuit) with high accuracy. Thus, since the perpendicular component of the magnetization direction is extremely reduced, noise generated from the soft magnetic layer 114 can be reduced.

  The composition of the first soft magnetic layer 114a and the second soft magnetic layer 114c as a preferred embodiment is FeCoTaZr. The composition of the spacer layer 14b as a preferred embodiment is ruthenium (Ru). The composition of the first soft magnetic layer 114a and the second soft magnetic layer 114c is not limited to these examples. Etc.), Co-based alloys (CoTaZr, CoZrNb, CoB, etc.) and the like can be used.

  The orientation control layer 116 is a layer used in a preferred embodiment according to the present invention, and has a function of protecting the soft magnetic layer 114 and a function of promoting alignment of crystal grains of the underlayer 118. The material of the orientation control layer 116 can be selected from Ni, Cu, Pt, Pd, Zr, Hf, and Nb. Furthermore, it is good also as an alloy which contains these metals as a main component and contains any one or more additional elements of Ti, V, Ta, Cr, Mo, and W. For example, NiW, CuW, or CuCr can be suitably selected.

  The underlayer 118 is a layer used in a preferred embodiment according to the present invention, and the crystal of the hcp structure of the magnetic recording layer 122 can be grown as a granular structure. Such a base layer 118 has an hcp structure. Here, as the crystal orientation of the underlayer 118 is higher, the orientation of the magnetic recording layer 122 can be improved. As a material for such an underlayer, Ru is widely used, but in addition to Ru, a Ru-based alloy such as RuCr or RuCo may be used. Ru has an hcp structure and can satisfactorily orient a magnetic recording layer containing Co as a main component.

  In the present embodiment, the base layer 118 has a two-layer structure made of Ru. In forming the second base layer 118b on the upper layer side, it is preferable to set the Ar gas pressure higher than when forming the first base layer 118a on the lower layer side. When the gas pressure is increased, the free movement distance of the plasma ions to be sputtered is shortened, so that the film formation rate is reduced and the crystal orientation can be improved. Further, by increasing the pressure, the size of the crystal lattice is reduced. Since the size of the Ru crystal lattice is larger than that of the Co crystal lattice, if the Ru crystal lattice is made smaller, it approaches that of Co, and the crystal orientation of the Co granular layer can be further improved.

The miniaturization promoting layer 120 is a nonmagnetic granular layer. A nonmagnetic granular layer is formed on the hcp crystal structure of the underlayer 118, and the granular layer of the first magnetic recording layer 122a is grown thereon, so that the magnetic granular layer can be grown from the initial growth stage (rise). Has the effect of separating. An example of the composition of such a miniaturization promoting layer 120 is nonmagnetic CoCr—SiO ₂ .

  Next, the magnetic recording layer 122 is a so-called granular magnetic recording layer. In the embodiment according to the present invention, the magnetic recording layer 122 includes, for example, crystal grains mainly composed of a magnetic substance such as cobalt (Co), and oxide, silicon (Si), chromium (Cr), or the like. It is preferable to include a ferromagnetic layer having a granular structure having a grain boundary portion mainly composed of a nonmagnetic substance.

  As the magnetic material constituting the ferromagnetic layer, a Co-based magnetic material such as a CoPt-based material or a CoPtCr-based material is particularly preferable. CoPt-based or CoPtCr-based magnetic materials have a high coercive force Hc, and the magnetization reversal generation magnetic field Hn can be set to a small value of less than zero, so it is possible to improve resistance to thermal fluctuations and a high S / N ratio Since it is obtained, it is suitable. By incorporating elements such as silicon (Si) and oxides into CoPt or CoPtCr magnetic materials, it is possible to segregate Si and oxides at the grain boundary portions of the magnetic crystal grains. Exchange interaction can be reduced to reduce medium noise and improve the S / N ratio at high recording density.

As the non-magnetic material for forming the non-magnetic regions, for example, silicon (Si), silicon oxide (SiO _X), chromium (Cr), chromium oxide (CrO _X), titanium oxide (TiO _2), zirconium oxide (ZrO ₂ ) and tantalum oxide (Ta ₂ O ₅ ) can be exemplified. The magnetic recording layer 122 may be a single layer, but is generally more preferably a multilayer. In this embodiment, the magnetic recording layer 122 includes a first magnetic recording layer 122a and a second magnetic recording layer 122b.

One example of the first magnetic recording layer 122a is a CoCrPt-Oxide hcp crystal formed using a hard magnetic target made of CoCrPt containing chromium oxide (Cr ₂ O ₃ ) as an example of a nonmagnetic substance. Structure. Nonmagnetic substances segregate around the magnetic substance to form grain boundaries, and magnetic grains (magnetic grains) form a columnar granular structure. When the miniaturization promoting layer 120 is provided in the lower layer, the magnetic grains can be epitaxially grown continuously from the granular structure of the miniaturization promoting layer 12.

An example of the second magnetic recording layer 122c is a CoCrPt—TiO ₂ hcp crystal formed using a hard magnetic target made of CoCrPt containing titanium oxide (TiO ₂ ) as an example of a nonmagnetic substance. Structure. Also in the second magnetic recording layer 122c, the magnetic grains have a granular structure.

  In the present invention, when the magnetic recording layer is a multilayer, the properties or performances of the respective magnetic recording layers may be varied. For example, the atmospheric gas pressure of the first magnetic recording layer 122a is set to a high pressure of 3 Pa to 10 Pa. Thus, high Hc and Hn can be obtained by forming a film using a high-pressure atmospheric gas. Further, the atmospheric gas pressure of the second magnetic recording layer 122b is set to a low pressure of 0.6 Pa to 3 Pa. Thus, high impact resistance can be obtained by forming a film using a low-pressure atmosphere gas.

  In this embodiment, different materials (targets) are used for the first magnetic recording layer 122a and the second magnetic recording layer 122b. However, there is no need to use different materials, and the same composition and type are used. May be.

  The continuous layer (auxiliary recording layer) 124 forms a thin film (auxiliary recording layer) exhibiting high perpendicular magnetic anisotropy on the magnetic recording layer 122 as a granular recording layer, and the magnetic crystal grains in the granular recording layer and It constitutes a CGC structure (Coupled Granular Continuous) for exchange coupling. Thereby, in addition to the high density recording property and low noise property of the granular layer, the high heat resistance of the continuous film can be added.

  As a material for forming the continuous layer (auxiliary recording layer) 124, a material exhibiting perpendicular magnetic anisotropy, for example, a Co-based magnetic material is used. It may be composed of a single layer or a plurality of layers. As a material suitable for the continuous layer (auxiliary recording layer) 124 exhibiting such perpendicular magnetic anisotropy, for example, it is known to be composed of a CoCrPt alloy or a laminated film of a cobalt alloy and P or Pt. . Such a continuous layer (auxiliary recording layer) 124 is generally formed as a continuous layer containing no oxide as described in the background art.

  Here, in the present invention, a non-solid substance that is non-solid solution with the magnetic particles constituting the auxiliary recording layer is included. Further, in this auxiliary recording layer, when a Co-based alloy is selected as the main component of magnetic particles exhibiting perpendicular magnetic anisotropy, the non-solid solution substance is a non-solid solution with respect to cobalt (Co) For example, silver (Ag) is preferably used. By adding, for example, silver (Ag) that is insoluble in cobalt (Co), the exchange interaction between the magnetic particles in the auxiliary recording layer can be adjusted, and the dispersion of the magnetic particles can be improved. Therefore, it is easy to record and the S / N ratio of the recorded signal can be improved. This also makes it possible to achieve a high recording density as a perpendicular magnetic recording medium.

An example of the composition of such a continuous layer (auxiliary recording layer) 124 is CoCrPtBAg obtained by adding Ag as a non-solid solution material to CoCrPtB.
When, for example, CoCrPtBAg is used as the material of the continuous layer (auxiliary recording layer) 124, the addition amount of Co and Ag has a feature that the effect can be exerted even when the amount is small as will be apparent from examples described later. Usually, a sufficient effect is exhibited in the range of 0.1 at% or more and 10 at% with respect to Co, and preferably in the range of 1 to 5 at% with respect to Co.
The non-solid solution material is not limited to Ag. For example, at least one of Ta, W, and C may be selected.

The medium protective layer 126 is a protective layer for protecting the perpendicular magnetic recording layer from the impact of the magnetic head. Such a protective layer 126 is a layer provided in a preferred embodiment according to the present invention. For example, the protective layer 126 is formed by depositing carbon by a CVD method while maintaining a vacuum and including diamond-like carbon. . In general, carbon deposited by the CVD method has improved film hardness compared to that deposited by the sputtering method, so that the perpendicular magnetic recording layer can be protected more effectively against the impact from the magnetic head. For the medium protective layer 126, for example, a material such as C, SiO ₂ or ZrO ₂ can be used. From the viewpoint of increasing the recording density, the thickness of the medium protective layer is preferably 1 nm or more and 5 nm or less.

  An example of the lubricating layer 128 is obtained by forming a film of PFPE (perfluoropolyether) on the protective layer 126 by a dip coating method. Thereby, lubricity can be imparted to the protective layer 126 and wear between the magnetic head and the magnetic disk can be suppressed. For the lubricating layer 128, for example, a material such as fluorinated alcohol or fluorinated carboxylic acid can be used. The film thickness of the lubricating layer 128 is about 1 nm.

Hereinafter, the present invention will be described more specifically with reference to examples and comparative examples.
Example 1
Amorphous aluminosilicate glass was molded into a disk shape with a direct press to create a glass disk. The glass disk was subjected to grinding, polishing, and chemical strengthening in order to obtain a smooth nonmagnetic disk substrate 110 made of a chemically strengthened glass disk.

Next, continuous deposition from the adhesion layer 112 is performed using a DC magnetron sputtering apparatus using a film forming apparatus (attainment vacuum: 10 ⁻⁵ Pa or less) that is evacuated on the base surface of the obtained disk substrate 110. The layers were sequentially formed up to the layer 124.
First, a 10 nm CrTi layer is formed as an adhesion layer using a CrTi target, and then a 25 nm FeCoTaZr layer (first soft magnetic layer), a 0.7 nm Ru layer (spacer layer) are formed as the soft magnetic layer 114. 114b) and 25 nm FeCoTaZr layers (second soft magnetic layers) were further formed.

Next, a 5 nm NiW layer was formed as the orientation control layer 116, and two Ru layers (each 12 nm) were formed as the base layer 118. When forming the second base layer 118b on the upper layer side, the Ar gas pressure was set higher than when forming the first base layer 118a on the lower layer side.
Next, a nonmagnetic CoCr—SiO ₂ layer was formed as the miniaturization promoting layer 120.
Further, a first magnetic recording layer 122a and a second magnetic recording layer 122c were sequentially formed thereon as the magnetic recording layer 122.

The first magnetic recording layer 122a is formed of a CoCrPt-Oxide hcp crystal structure using a hard magnetic target made of CoCrPt containing chromium oxide (Cr ₂ O ₃ ) as an example of a nonmagnetic substance. Nonmagnetic substances segregated around the magnetic substance to form grain boundaries, and the magnetic grains (magnetic grains) formed columnar granular structures. The magnetic grains were epitaxially grown continuously from the granular structure of the miniaturization promoting layer.

For the second magnetic recording layer 122c, a CoCrPt—TiO ₂ hcp crystal structure was formed using a hard magnetic target made of CoCrPt containing titanium oxide (TiO ₂ ) as an example of a nonmagnetic material. Also in the second magnetic recording layer 122b, the magnetic grains formed a granular structure.

Here, it is also effective to insert an exchange coupling control layer made of a nonmagnetic material. As an example of the nonmagnetic material, Ru (or Co and oxide added to Ru) can be given. It is also effective to use a nonmagnetic CoCr—TiO ₂ target containing titanium oxide (TiO ₂ ). Both layers (first exchange coupling control layer 122b and second exchange coupling control layer 122d) as the exchange coupling control layer between the first magnetic recording layer 122a, the second magnetic recording layer 122c, and the auxiliary recording layer, there is only one of the layers Regardless, the effects of the present invention are equivalent.

The continuous layer (auxiliary recording layer) was formed using a target made of CoCrPtAg in which the target composition was changed within a range of 2 to 4 at% of Ag added to Co.
Further, as a control example, a target made of CoCrPt without adding silver (Ag) was used.

  Next, as the medium protective layer, a carbon-based protective layer made of diamond-like carbon was formed by depositing carbon by a CVD method while maintaining a vacuum. The film thickness of the carbon-based protective layer was 5 nm. Thereafter, a lubricating layer made of PFPE (perfluoropolyether) was formed by a dip coating method. The thickness of the lubricating layer was 1 nm.

The following evaluations were performed using the perpendicular magnetic recording media of the above examples. In Table 1, all units of magnetic properties are expressed in Oersted [Oe].
[Evaluation of magnetic properties]
Evaluation of the magnetic properties was performed using a perpendicular magnetic property Kerr effect measuring apparatus (model Model-32kt Gauss meter, manufactured by Tencor, USA). The coercive force Hc, the saturation magnetic force Hs, and the nuclear growth magnetic field Hn were evaluated. Further, the total magnetic moment (Ms) per unit volume of the continuous layer (auxiliary recording layer) was evaluated with a vibrating sample magnetometer (VSM).

[Recording and playback characteristics evaluation]
The recording / reproduction characteristics of a perpendicular magnetic recording medium were measured using an R / W analyzer, a single pole head with a recording side shield, and a perpendicular magnetic recording system magnetic head with a TMR element on the reproduction side. (Hereinafter referred to as OW2) and magnetic effective width (MWw). Here, the magnetic effective width (MWw) was calculated from the track profile using a spin stand.
The bit error rate (signal-to-noise ratio, hereinafter, bER hereinafter), in 1300kFCI using a spin stand, Record 10 ⁷ known random data, examines the read error number, the following formula ( Obtained by 1).
bER = log (number of errors / number of data) (1)
Further, the disk reliability was evaluated by a corrosion evaluation and a pin on evaluation. In the corrosion evaluation, the amount of impurities deposited from the outermost surface was evaluated by leaving the disk under high temperature and high humidity conditions and measuring the number of collision spots per unit area. In the pin-on evaluation, the pin was pressed against the rotated disk surface with a predetermined load, the pass count until the film was broken was measured, and the film strength was evaluated.

[Evaluation results]
Table 1 shows the measurement results of the magnetostatic characteristics of the perpendicular magnetic recording disk. In a disk in which all the layers were formed with the same film thickness, the coercive force (Hc) and the nuclear growth magnetic field (with the addition of 2 at% and 4 at% of silver (Ag) were compared with those without adding silver (Ag). It can be confirmed that the saturation magnetic force (Hs) decreases as the addition amount of silver (Ag) increases while Hn) is equivalent. Further, it can be confirmed that the total magnetic moment amount (Ms) is increased by adding silver (Ag) although the Co volume is decreased.

FIG. 3 shows the relationship between the magnetic execution width (MWw) and OW2, which is a parameter representing signal write performance. Here, OW2 indicates that the larger the absolute value is, the better the performance is. Therefore, from FIG. 3, since the signal writing performance is increased by adding Ag, this magnetic execution width is increased. Within the range of (MWw), it can be confirmed that the recording / reproducing characteristics are improved by adding Ag.
FIG. 4 shows the relationship between the bit error rate (bER) and the magnetostatic characteristics (SN) with respect to the magnetic execution width (MWw). It can be confirmed that the SN ratio and bER (digit) are improved in the same magnetic execution width MWw (track width).

Further, from the corrosion test results shown in FIG. 5, it was confirmed that the number of corrosion spots was drastically reduced by the addition of silver (Ag), and that high reliability was obtained even under conditions of high temperature and high humidity by the addition of silver. Is done.
Moreover, from the result in the pin-on durability test shown in FIG. 6, it is confirmed that the strength of the magnetic film is increased by the addition of silver.

From the above results, the mechanism of the effect obtained by adding Ag to the continuous layer was estimated as follows.
In the continuous layer (auxiliary recording layer) to which Ag is not added, Cr and B are segregated around Co. However, not all Co atoms are present in the crystals (grains) but are also slightly contained in the segregated Cr and B. Co atoms contained in the segregated Cr and B have magnetism but have small grains. Therefore, they are not ferromagnetic and do not contribute to Ms. Addition of Ag, which is insoluble in Co, allows the Co atoms in the segregated Cr and B to be expelled into the Co grains, and Co atoms that have not contributed to Ms increase Ms. Contribute. For this reason, the dispersion of the size of the Co grains decreases and Hs decreases. OW2 has improved with a decrease in Hs. In addition, since the grain boundary is clear, noise is reduced, and SN and bER are improved.

  As described above, in the present invention, a higher recording density can be realized by adding, for example, Ag to the continuous layer (auxiliary recording layer) in the hard disk medium. In addition, the physical resistance to the reliability and durability of the disk is also improved. Furthermore, the effect of Ag can promote the separation of the Co particles and other substances (Cr, Pt, B) in the continuous layer (auxiliary recording layer) and reduce the dispersion of the Co particles. Leads to an improvement in the ratio. Further, an increase in Ms is also an effect that contributes to separation promotion.

  The perpendicular magnetic recording medium according to the present invention is promising in that it can provide a perpendicular magnetic recording medium that can be mounted on various magnetic disk devices that are required to have a high recording density.

110 disk 112 adhesion layer 114 soft magnetic layer 118 underlayer 120 miniaturization promoting layer 122 magnetic recording layer (granular magnetic recording layer)
124 Auxiliary recording layer (continuous layer)
126 Medium protective layer 128 Lubricating layer

Claims (4)

A perpendicular magnetic recording medium comprising at least a granular magnetic recording layer and an auxiliary recording layer having magnetic particles exhibiting perpendicular magnetic anisotropy exchange-coupled to magnetic crystal grains in the granular magnetic recording layer,
The auxiliary recording layer includes a non-solid solution substance that is non-solid solution with the magnetic particles constituting the auxiliary recording layer ,
The auxiliary recording layer is made of a Co-based alloy containing cobalt (Co) as a main component of magnetic particles exhibiting perpendicular magnetic anisotropy, and the non-solid substance is a non-solid solution with respect to cobalt (Co). there silver (Ag) or, W, perpendicular magnetic recording medium, wherein at least one is selected Rukoto of C.   The perpendicular magnetic recording medium according to claim 1, wherein the concentration of the non-solid solution material is in a range of 0.1 at% or more and 10 at%.   The granular magnetic recording layer has a granular structure having a grain boundary portion composed of magnetic crystal grains mainly composed of cobalt (Co) and nonmagnetic particles that magnetically separate magnetic crystal grains at the grain boundaries of the magnetic crystal grains. The perpendicular magnetic recording medium according to claim 1, further comprising a ferromagnetic layer.   An exchange coupling control layer made of a nonmagnetic material that controls exchange coupling between the granular magnetic recording layer and the auxiliary recording layer is interposed between the granular magnetic recording layer and the auxiliary recording layer. The perpendicular magnetic recording medium according to any one of claims 1 to 3, wherein:

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