U.S. patent application number 15/267438 was filed with the patent office on 2017-08-31 for magnetic recording head and disk device comprising the same.
The applicant listed for this patent is Kabushiki Kaisha Toshiba. Invention is credited to Tomomi Funayama, Tomoko Taguchi.
Application Number | 20170249960 15/267438 |
Document ID | / |
Family ID | 59654121 |
Filed Date | 2017-08-31 |
United States Patent
Application |
20170249960 |
Kind Code |
A1 |
Taguchi; Tomoko ; et
al. |
August 31, 2017 |
MAGNETIC RECORDING HEAD AND DISK DEVICE COMPRISING THE SAME
Abstract
According to one embodiment, a magnetic recording head includes
an air bearing surface, a magnetic core including a main magnetic
pole and a write shield arranged to face the main magnetic pole
with a write gap, a coil, and a high-frequency oscillator provided
between the main magnetic pole and the write shield in the write
gap. The magnetic core includes an opposite surface facing a film
surface of the high-frequency oscillator, a magnetic layer, and a
nonmagnetic layer in which magnetic microparticles are dispersed.
The nonmagnetic layer is provided outside the magnetic layer in at
least a part of the opposite surface of the magnetic core.
Inventors: |
Taguchi; Tomoko; (Kunitachi
Tokyo, JP) ; Funayama; Tomomi; (Fuchu Tokyo,
JP) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Kabushiki Kaisha Toshiba |
Tokyo |
|
JP |
|
|
Family ID: |
59654121 |
Appl. No.: |
15/267438 |
Filed: |
September 16, 2016 |
Current U.S.
Class: |
1/1 |
Current CPC
Class: |
G11B 5/17 20130101; G11B
5/1278 20130101; G11B 2005/0024 20130101; G11B 5/6082 20130101;
G11B 5/235 20130101; G11B 5/3146 20130101; G11B 5/3909
20130101 |
International
Class: |
G11B 5/39 20060101
G11B005/39; G11B 5/127 20060101 G11B005/127; G11B 5/17 20060101
G11B005/17; G11B 5/60 20060101 G11B005/60 |
Foreign Application Data
Date |
Code |
Application Number |
Feb 29, 2016 |
JP |
2016-037316 |
Claims
1. A magnetic recording head comprising: an air bearing surface; a
magnetic core comprising a main magnetic pole formed of a
high-magnetic-permeability material and comprising an apical end
portion extending to the air bearing surface; and a write shield
formed of a high-magnetic-permeability material, the write shield
being arranged to face the main magnetic pole through a
nonconductive layer on a deep side apart from the air bearing
surface, and to face the apical end portion of the main magnetic
core on the air bearing side through a conductive nonmagnetic layer
with a write gap; a coil provided so as to pass across the magnetic
core; a high-frequency oscillator provided between the main
magnetic pole and the write shield in the write gap; and a pair of
current terminals for supplying direct current between the main
magnetic pole and the write shield, wherein the magnetic core
comprises an opposite surface facing a film surface of the
high-frequency oscillator, a magnetic layer formed of a
high-magnetic-permeability material, and a nonmagnetic layer in
which magnetic microparticles are dispersed, the nonmagnetic layer
being provided outside the magnetic layer in at least a part of the
opposite surface of the magnetic core.
2. The magnetic recording head of claim 1, wherein the write shield
comprises an opposite surface facing the apical end portion of the
main magnetic pole with the write gap being interposed, the
magnetic layer is exposed to the opposite surface of the write
shield and faces the high-frequency oscillator, and the nonmagnetic
layer covers an opposite side of the magnetic layer relative to the
high-frequency oscillator in the write shield.
3. The magnetic recording head of claim 2, wherein the
high-frequency oscillator comprises the film surface extending in a
direction intersecting with the air bearing surface, the magnetic
layer comprises an opposite surface facing the high-frequency
oscillator, an area of the opposite surface of the magnetic layer
is greater than an area of the film surface of the high-frequency
oscillator, and the nonmagnetic layer is away from an edge of the
high-frequency oscillator.
4. The magnetic recording head of claim 1, wherein the magnetic
core comprises a side shield connected to the write shield and
provided outside the main magnetic pole in a width direction of the
main pole with a gap, the side shield comprising an opposite
surface facing the high-frequency oscillator, the magnetic layer is
provided on the opposite surface of the side shield, and the
nonmagnetic layer is provided outside the magnetic layer relative
to the high-frequency oscillator in the side shield.
5. The magnetic recording head of claim 4, wherein the write shield
comprises an opposite surface facing the apical end portion of the
main magnetic pole with the write gap being interposed, and the
magnetic core comprises: a magnetic layer which is provided on a
write shield side, is exposed to the opposite surface of the write
shield and is continuous with the magnetic layer on the side
shield; and a nonmagnetic layer which is provided on the write
shield side, is provided on a side opposite to the high-frequency
oscillator of the magnetic layer in the write shield, is continuous
with the nonmagnetic layer of the side shield, and contains
dispersed magnetic microparticles.
6. The magnetic recording head of claim 1, wherein the magnetic
core comprises the magnetic layer constituting the apical end
portion of the main magnetic pole, and the nonmagnetic layer is
provided outside the magnetic layer relative to the high-frequency
oscillator in the main magnetic pole.
7. The magnetic recording head of claim 1, wherein the
high-frequency oscillator comprises the film surface extending in a
direction intersecting with the air bearing surface, the magnetic
layer comprises an opposite surface facing the high-frequency
oscillator, an area of the opposite surface of the magnetic layer
is greater than an area of the film surface of the high-frequency
oscillator, and the nonmagnetic layer is away from an edge of the
high-frequency oscillator.
8. The magnetic recording head of claim 1, wherein the magnetic
microparticles are dispersed in an entire part of the nonmagnetic
layer substantially uniformly, and a contained amount of the
magnetic microparticles is set to 5 to 20%.
9. A disk device comprising: a disk-shaped recording medium
comprising a magnetic recording layer; and the magnetic recording
head of claim 1, configured to record data onto the recording
medium.
10. The disk device of claim 9, wherein the write shield comprises
an opposite surface facing the apical end portion of the main
magnetic pole with the write gap being interposed, the magnetic
layer is exposed to the opposite surface of the write shield and
faces the high-frequency oscillator, and the nonmagnetic layer
covers an opposite side of the magnetic layer relative to the
high-frequency oscillator in the write shield.
11. The disk device of claim 10, wherein the high-frequency
oscillator comprises the film surface extending in a direction
intersecting with the air bearing surface, the magnetic layer
comprises an opposite surface facing the high-frequency oscillator,
an area of the opposite surface of the magnetic layer is greater
than an area of the film surface of the high-frequency oscillator,
and the nonmagnetic layer is away from an edge of the
high-frequency oscillator.
12. The disk device of claim 9, wherein the magnetic core comprises
a side shield connected to the write shield and provided outside
the main magnetic pole in a width direction of the main pole with a
gap, the side shield comprising an opposite surface facing the
high-frequency oscillator, the magnetic layer is provided on the
opposite surface of the side shield, and the nonmagnetic layer is
provided outside the magnetic layer relative to the high-frequency
oscillator in the side shield.
13. The disk device of claim 12, wherein the write shield comprises
an opposite surface facing the apical end portion of the main
magnetic pole with the write gap being interposed, and the magnetic
core comprises: a magnetic layer which is provided on a write
shield side, is exposed to the opposite surface of the write shield
and is continuous with the magnetic layer on the side shield; and a
nonmagnetic layer which is provided on the write shield side, is
provided on a side opposite to the high-frequency oscillator of the
magnetic layer in the write shield, is continuous with the
nonmagnetic layer of the side shield, and contains dispersed
magnetic microparticles.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is based upon and claims the benefit of
priority from Japanese Patent Application No. 2016-037316, filed
Feb. 29, 2016, the entire contents of which are incorporated herein
by reference.
FIELD
[0002] Embodiments described herein relate generally to a magnetic
recording head comprising a high-frequency-assisted element, and a
disk device comprising the magnetic recording head.
BACKGROUND
[0003] In recent years, a magnetic head for perpendicular magnetic
recording has been suggested to realize high recording density,
large capacity or miniaturization of a magnetic disk device as a
disk device. In this type of magnetic head, a recording head
includes a main magnetic pole which produces a perpendicular
magnetic field, a write shield magnetic pole provided on the
trailing side of the main magnetic pole across an intervening write
gap, and a coil for supplying a magnetic flux to the main magnetic
pole. Further, the following high-frequency (microwave) assisted
head has been suggested. In the high-frequency assisted head, a
high-frequency (microwave) oscillator such as a spin-torque
oscillator is provided in the write gap between the write shield
magnetic pole and the main magnetic pole. Current is supplied to
the spin-torque oscillator through the main magnetic pole and the
write shield magnetic pole.
[0004] In the high-frequency-assisted head, the spin injection
layer and the oscillation layer of the high-frequency oscillator
are allocated in the write gap. In the high-frequency-assisted head
having this structure, the magnetization near the surface of the
write shield or the main magnetic pole facing the surface of the
oscillation layer vibrates so as to be synchronized with the
rotation of magnetization of the oscillation layer. Thus, a spin
wave is generated. This spin wave may disturb the rotation of
magnetization of the high-frequency oscillator and inhibit the
assist effect.
BRIEF DESCRIPTION OF THE DRAWINGS
[0005] FIG. 1 is a perspective view showing a hard disk drive (HDD)
according to a first embodiment.
[0006] FIG. 2 is a side view showing a magnetic head and a
suspension in the HDD.
[0007] FIG. 3 is an enlarged cross-sectional view showing a head
portion of the magnetic head.
[0008] FIG. 4 is a perspective view schematically showing a
recording head of the magnetic head.
[0009] FIG. 5 is an enlarged perspective view showing an ABS-side
end portion of the recording head.
[0010] FIG. 6 is an enlarged cross-sectional view taken along a
track center and showing the ABS-side end portion of the recording
head.
[0011] FIG. 7 is an enlarged plan view showing the ABS-side end
portion of the recording head when viewed from the ABS side.
[0012] FIG. 8 shows a comparison between the magnetic recording
head of the present embodiment, the magnetic recording head of
comparative example 1 and the magnetic recording head of
comparative example 2 with respect to the distribution of the
magnetic field strength in the track travel direction.
[0013] FIG. 9 shows a comparison between the magnetic recording
head of the present embodiment, the magnetic recording head of
comparative example 1 and the magnetic recording head of
comparative example 2 with respect to the relationship between the
maximum magnetic field strength and the magnetic field
gradient.
[0014] FIG. 10 shows the relationship between distance d from the
track center of the magnetic head to a nonmagnetic layer and the
angle of rotation of magnetization from the film surface of a
high-frequency oscillator.
[0015] FIG. 11 shows the relationship between distance d and the
maximum magnetic field strength of the magnetic head.
[0016] FIG. 12 shows the relationship between the concentration of
magnetic microparticles and the angle of oscillatory rotation of
the high-frequency oscillator when distance d is 20 nm and 60
nm.
[0017] FIG. 13 shows the relationship between the concentration of
magnetic microparticles and the maximum magnetic field strength
when distance d is 20 nm.
[0018] FIG. 14 is an enlarged perspective view schematically
showing the apical end portion of a magnetic recording head in an
HDD according to a second embodiment.
[0019] FIG. 15 is a plan view showing the apical end portion of the
magnetic recording head when viewed from the ABS side according to
the second embodiment.
[0020] FIG. 16 is an enlarged perspective view schematically
showing the apical end portion of a magnetic recording head in an
HDD according to a third embodiment.
[0021] FIG. 17 is a plan view showing the apical end portion of the
magnetic recording head when viewed from the ABS side according to
the third embodiment.
[0022] FIG. 18 is an enlarged perspective view schematically
showing the apical end portion of a magnetic recording head in an
HDD according to a fourth embodiment.
[0023] FIG. 19 is a plan view showing the apical end portion of the
magnetic recording head when viewed from the ABS side according to
the fourth embodiment.
[0024] FIG. 20 is an enlarged perspective view schematically
showing the apical end portion of a magnetic recording head in an
HDD according to a fifth embodiment.
[0025] FIG. 21 is a plan view showing the apical end portion of the
magnetic recording head when viewed from the ABS side according to
the fifth embodiment.
[0026] FIG. 22 is an enlarged perspective view schematically
showing the apical end portion of a magnetic recording head in an
HDD according to a sixth embodiment.
DETAILED DESCRIPTION
[0027] Various embodiments will be described hereinafter with
reference to the accompanying drawings. In general, according to
one embodiment, a magnetic recording head comprises: an air bearing
surface; a magnetic core comprising a main magnetic pole formed of
a high-magnetic-permeability material and comprising an apical end
portion extending to the air bearing surface; and a write shield
formed of a high-magnetic-permeability material, the write shield
being arranged to face the main magnetic pole through a
nonconductive layer on a deep side apart from the air bearing
surface, and to face the apical end portion of the main magnetic
core on the air bearing side through a conductive nonmagnetic layer
with a write gap; a coil provided so as to pass across the magnetic
core; a high-frequency oscillator provided between the main
magnetic pole and the write shield in the write gap; and a pair of
current terminals for supplying direct current between the main
magnetic pole and the write shield. The magnetic core comprises an
opposite surface facing a film surface of the high-frequency
oscillator, a magnetic layer formed of a high-magnetic-permeability
material, and a nonmagnetic layer in which magnetic microparticles
are dispersed, the nonmagnetic layer being provided outside the
magnetic layer in at least a part of the opposite surface of the
magnetic core.
First Embodiment
[0028] FIG. 1 shows an internal structure of a hard disk drive
(HDD) according to a first embodiment, with a top cover detached
therefrom, and FIG. 2 shows a magnetic head in a flying state. As
shown in FIG. 1, the HDD comprises a housing 10. The housing 10
comprises a base 12 having the shape of a rectangular box which is
open on its upper side, and a top cover (not shown) which is
secured to the base 12 by a plurality of screws and closes the
upper end opening of the base 12. The base 12 includes a
rectangular bottom wall 12a and a sidewall 12b provided upright
along the peripheral edge of the bottom wall.
[0029] As recording media, for example, two magnetic disks 16 are
provided in the housing 10. Further, a spindle motor 18 is provided
in the housing 10 as a drive section which supports and rotates the
magnetic disks 16. The spindle motor 18 is provided on the bottom
wall 12a. Each magnetic disk 16 is formed so as to have a diameter
of, for example, approximately 2.5 inches (6.35 cm) and comprises a
magnetic recording layer on at least one of the upper and lower
surfaces. The magnetic disks 16 engage coaxially with a hub (not
shown) of the spindle motor 18, and are clamped by a clamp spring
27, thereby being fixed to the hub. The magnetic disks 16 are
supported parallel to the bottom wall 12a of the base 12. The
magnetic disks 16 are rotated at a predetermined speed by the
spindle motor 18.
[0030] A plurality of magnetic heads 17 and a carriage assembly 22
are provided in the housing 10. The magnetic heads 17 are
configured to write and read data to and from the magnetic disks
16. The carriage assembly 22 supports the magnetic heads 17 such
that they are movable with respect to the magnetic disks 16. In the
housing 10 are arranged a voice coil motor (VCM) 24, a ramp load
mechanism 25, a latch mechanism 26 and a flexible printed circuit
(FPC) unit 21. The VCM 24 rotates and positions the carriage
assembly 22. When the magnetic heads 17 are moved to the outermost
circumferential part of the magnetic disks 16, the ramp load
mechanism 25 holds the magnetic heads 17 in unload positions where
they are separated from the magnetic disks 16. The latch mechanism
26 holds the carriage assembly 22 in a retreat position when an
impact, etc., acts on the HDD. The FPC unit 21 includes electronic
components such as a conversion connector.
[0031] A control circuit board (not shown) is screwed to the
external surface of the base 12 and faces the bottom wall 12a. The
control circuit board controls the operation of the spindle motor
18, and controls the operations of the VCM 24 and the magnetic
heads 17 through the FPC unit 21.
[0032] The carriage assembly 22 comprises a bearing unit 28 secured
onto the bottom wall 12a of the base 12, a plurality of arms 32
extending from the bearing unit 28, and suspensions 34 which are
allowed to elastically deform and have the shape of a slender
plate. The magnetic heads 17 are supported at the extended ends of
the suspensions 34. The suspensions 34 and the magnetic heads 17
face each other with the magnetic disks 16 being interposed.
[0033] As shown in FIG. 2, each magnetic head 17 is structured as a
flying head, and comprises a slider 42 having substantially the
shape of a rectangular parallelepiped and a head portion 44 for
reading and writing at the outflow end (trailing end) of the slider
42. The magnetic head 17 is secured to a gimbal spring 41 provided
at the apical end portion of the suspension 34. As shown in FIG. 1
and FIG. 2, each magnetic head 17 is electrically connected to the
FPC unit 21 via a trace member 35 secured onto the suspension 34
and the arm 32, and a relay FPC 37.
[0034] Now, the structures of the magnetic disks 16 and the
magnetic heads 17 are described in detail. FIG. 3 is an enlarged
cross-sectional view showing the head portion 44 of the magnetic
head 17 and the magnetic disk 16.
[0035] As shown in FIG. 1 to FIG. 3, the magnetic disk 16 comprises
a substrate 101 formed of a nonmagnetic material in the shape of a
circular disk having a diameter of, for example, approximately 2.5
inches (6.35 cm). On each surface of the substrate 101, a soft
magnetic layer 102 as a foundation layer, a magnetic recording
layer 103 and a protective film layer 104 are stacked in order. The
soft magnetic layer 102 is formed of a material showing soft
magnetic properties. The magnetic recording layer 103 has magnetic
anisotropy in a direction perpendicular to the disk surface.
[0036] As shown in FIG. 2 and FIG. 3, the slider 42 of the magnetic
head 17 is formed by, for example, a sintered body (AlTiC) of
alumina and titanium-carbide. The head portion 44 is formed by
stacking thin films. The slider 42 comprises a rectangular
disk-facing surface (air bearing surface [ABS]) 43 facing the
surface of the magnetic disk 16. The slider 42 is caused to fly by
an air flow C produced between the disk surface and the ABS 43 by
the rotation of the magnetic disk 16. The direction of the air flow
C conforms to the rotational direction B of the magnetic disk 16.
The slider 42 is provided such that the longitudinal direction of
the ABS 43 substantially conforms to the direction of the air flow
C relative to the surface of the magnetic disk 16.
[0037] The slider 42 comprises a leading end 42a located on the
inflow side of the air flow C and a trailing end 42b located on the
outflow side of the air flow C. On the ABS 43 of the slider 42, for
example, a leading step, a trailing step, a side step and a
negative-pressure cavity are formed (not shown).
[0038] As shown in FIG. 3, the head portion 44 comprises a reading
head 54 and a recording head (magnetic recording head) 58 formed by
a thin-film process at the trailing end 42b of the slider 42. Thus,
the head portion 44 is formed as a separation type of magnetic
head. The reading head 54 and the recording head 58 are covered by
a protective insulating film 76 excluding the portions exposed to
the ABS 43 of the slider 42. The protective insulating film 76
forms the outer shape of the head portion 44.
[0039] The reading head 54 comprises a magnetic film 55 having a
magnetoresistive effect, and shield films 56 and 57 provided on the
trailing and leading sides of the magnetic film 55 so as to
sandwich the magnetic film 55. The lower ends of the magnetic film
55 and the shield films 56 and 57 are exposed to the ABS 43 of the
slider 42.
[0040] The recording head 58 is provided on the trailing end 42b
side of the slider 42 relative to the reading head 54. FIG. 4 is a
perspective view schematically showing the recording head 58 and
the magnetic disk 16. FIG. 5 is an enlarged perspective view
showing the ABS-side end portion of the recording head 58. FIG. 6
is an enlarged cross-sectional view taken along the track center
and showing the end portion of the recording head 58 on the
magnetic disk 16 side. FIG. 7 is an enlarged perspective view
showing the end portion of the recording head 58 on the magnetic
disk 16 side.
[0041] As shown in FIG. 3 to FIG. 6, the recording head 58
comprises: a main magnetic pole 60 which is formed of a soft
magnetic material and a high-saturated magnetized material
producing a recording magnetic field in a direction perpendicular
to the surface of the magnetic disk 16; a trailing shield (write
shield) 62 which is provided on the trailing side of the main
magnetic pole 60 to effectively close the magnetic path via the
soft magnetic layer 102 immediately under the main magnetic pole
60, and is formed of a soft magnetic material; a recording coil 64
which winds around a magnetic core (magnetic circuit) including the
main magnetic pole 60 and the trailing shield 62, and is provided
to supply a magnetic flux to the main magnetic pole 60 when a
signal is written to the magnetic disk 16; and a high-frequency
(microwave) oscillator, for example, a spin torque oscillator (STO)
65 which is formed of a nonmagnetic conductive material and is
provided in the portion facing the ABS 43 between an apical end
portion 60b of the main magnetic pole 60 on the ABS 43 side and the
trailing shield 62.
[0042] The main magnetic pole 60 extends substantially
perpendicularly to the surface of the magnetic disk 16 and the ABS
43. The lower end portion of the main magnetic pole 60 on the ABS
43 side comprises a tapered portion 60a and the apical end portion
60b. The tapered portion 60a tapers towards the ABS 43 and narrows
down into a funnel shape in the track width direction. The apical
end portion 60b extends from the tapered portion 60a to the ABS 43
and has a predetermined width. The distal end, in other words, the
lower end of the apical end portion 60b is exposed to the ABS 43 of
the magnetic head. The width of the apical end portion 60b in the
track width direction T1 substantially corresponds to the track
width TW in the magnetic disk 16. The main magnetic pole 60 extends
substantially perpendicularly to the ABS 43 and comprises a
shield-side end surface 60c facing the trailing side.
[0043] The trailing shield 62 has substantially an L-shape. The
trailing shield 62 comprises an apical end portion 62a facing the
apical end portion 60b of the main magnetic pole 60 across an
intervening write gap, and a connection portion (back gap portion)
50 which is away from the ABS 43 and is connected to the main
magnetic pole 60. The connection portion 50 is connected to the
upper portion of the main magnetic pole 60, in other words, to the
upper portion away from the ABS 43 toward the deep side or the
upper side, via a nonconductive element 52.
[0044] The apical end portion 62a of the trailing shield 62 has the
shape of a slender rectangle. The lower end surface of the trailing
shield 62 is exposed to the ABS 43 of the slider 42. A leading-side
end surface (main-magnetic-pole-side end surface) 62b of the apical
end portion 62a extends substantially perpendicularly to the ABS 43
and extends in the track width direction of the magnetic disk 16.
The leading-side end surface 62b faces the shield-side end surface
60c of the main magnetic pole 60 substantially parallel across an
intervening write gap WG in the lower end portion of the main
magnetic pole 60 (in other words, in a part of the apical end
portion 60b and the tapered portion 60a).
[0045] As shown in FIG. 5, FIG. 6 and FIG. 7, the STO 65 is
provided between the apical end portion 60b of the main magnetic
pole 60 and the trailing shield 62 in the write gap WG, and is
partially exposed to the ABS 43. The STO 65 comprises a spin
injection layer 65a, an intermediate layer (nonmagnetic conductive
layer) 65b and an oscillation layer 65c, and is structured by
stacking these layers in order from the main magnetic pole 60 side
to the trailing shield 62 side, in other words, in a direction
opposite to the travel direction D of the magnetic head 17. The
spin injection layer 65a is attached to the shield-side end surface
60c of the main magnetic pole 60 via a nonmagnetic conductive layer
(foundation layer) 67a. The oscillation layer 65c is attached to
the leading-side end surface 62b of the trailing shield 62 via a
nonmagnetic conductive layer (cap layer) 67b. The stacking order of
the spin injection layer 65a, the intermediate layer 65b and the
oscillation layer 65c may be opposite to the above order. In other
words, these layers may be stacked in order from the trailing
shield 62 side to the main magnetic pole 60 side.
[0046] Each of the spin injection layer 65a, the intermediate layer
65b and the oscillation layer 65c comprises a stack surface or a
film surface extending in a direction intersecting with the ABS 43,
for example, in a direction perpendicular to the ABS 43. The lower
end surface of the STO 65 is exposed to the ABS 43 and is formed as
the same plane as the ABS 43. Width SW of the STO 65 is set so as
to be substantially equal to or less than the track width TW.
Height SH of the STO 65 (the height in a direction perpendicular to
the ABS 43) is substantially equal to or less than the height of
the leading-side end surface 62b of the trailing shield 62. Width
SW and height SH of the STO 65 are set to, for example,
approximately 40 nm.
[0047] In at least one of the trailing shield 62 and the main
magnetic pole 60 included in the magnetic core, a magnetic layer 82
formed of a high-magnetic-permeability material is provided in the
area facing the STO 65. Further, a nonmagnetic layer 84 is provided
outside the magnetic layer 82. Magnetic microparticles are
dispersed in the nonmagnetic material layer 84.
[0048] As shown in FIG. 5, FIG. 6 and FIG. 7, in the present
embodiment, the magnetic layer 82 is provided in the apical end
portion of the trailing shield 62. For example, the magnetic layer
82 has substantially a rectangular shape, and is exposed to the
leading-side end surface 62b and the ABS 43. The side surfaces and
the bottom surface of the magnetic layer 82 constitute a part of
the leading-side end surface 62b and a part of the ABS 43.
[0049] The area of the opposite surface of the magnetic layer 82
facing the STO 65, in other words, the area of the magnetic layer
82 exposed to the leading-side end surface 62b, is formed so as to
be greater than that of the opposite surface (film surface) of the
oscillation layer 65c. For example, on the leading-side end surface
62b, height MH of the magnetic layer 82 (in other words, the height
from the ABS 43 in the depth direction) is formed so as to be
greater than height SH of the STO 65. On the leading-side end
surface 62b, width MW of the magnetic layer 82 (in other words, the
width in the track width direction T1) is formed so as to be
greater than width SW of the STO 65. In the track width direction
T1, distance d from the track center S to the side edge of the
magnetic layer 82 is formed so as to be greater than or equal to a
half-width SW of the STO 65 (SW/2). Thus, the magnetic layer 82
faces the entire part of the stack surface of the STO 65 and
extends to both sides of the STO 65 upward and in the width
direction beyond the side edges of the STO 65.
[0050] The thickness of the magnetic layer 82, in other words, the
thickness in a direction perpendicular to the film surface of the
STO 65, is arbitrarily adjustable.
[0051] The nonmagnetic layer (granular magnetic layer) 84 is
provided outside the magnetic layer 82 and covers the circumference
of the magnetic layer 82. The nonmagnetic layer 84 is stacked on
the back surface of the magnetic layer 82 on the trailing side (in
other words, the surface on a side opposite to the STO 65 side),
the upper surface of the magnetic layer 82 and the both side
surfaces of the magnetic layer 82 in the track width direction. The
nonmagnetic layer 84 is exposed to the leading-side end surface 62b
and the ABS 43. The side surfaces and the bottom surface of the
magnetic layer 82 constitute a part of the leading-side end surface
62b and a part of the ABS 43.
[0052] The nonmagnetic layer 84 formed in the above manner
comprises a nonmagnetic material such as alumina (Al2O3) or
ruthenium (Ru). Magnetic microparticles formed of an alloy
containing Co, Fe, Ni, etc., are dispersed in the nonmagnetic layer
84 substantially uniformly. The diameter of magnetic microparticles
is preferably several tens of nanometers to several micrometers.
The contained amount (concentration) of magnetic microparticles is
preferably approximately 5 to 25% per unit volume. By controlling
the contained amount of magnetic microparticles, the nonmagnetic
properties of the nonmagnetic layer 84 can be adjusted. The
thickness of the nonmagnetic layer 84 can be arbitrarily
adjusted.
[0053] As shown in FIG. 3, the main magnetic pole 60 and the
trailing shield 62 are connected to a power source 74 via an
interconnection 66 and connection terminals (current terminals) 70
and 72. A current circuit is structured such that current Iop is
supplied from the power source 74 to the interconnection 66, the
main magnetic pole 60, the STO 65 and the trailing shield 62 in
series.
[0054] For example, the recording coil 64 winds around the
connection portion 50 between the main magnetic pole 60 and the
trailing shield 62. The recording coil 64 is connected to a
terminal 78 via an interconnection 77. A second power source 80 is
connected to the terminal 78. Recording current Iw supplied from
the second power source 80 to the recording coil 64 is controlled
by the control unit of the HDD. When a signal is written to the
magnetic disk 16, a predetermined recording current Iw is supplied
from the second power source 80 to the recording coil 64. A
magnetic flux is supplied to the main magnetic pole 60, thereby
producing a recording magnetic field.
[0055] According to the HDD structured in the above manner, when
the VCM 24 is driven, the carriage assembly 22 is rotated. The
magnetic head 17 is moved onto the desired track of the magnetic
disk 16, and the position of the magnetic head 17 is determined. As
shown in FIG. 2, the magnetic head 17 is caused to fly by the air
flow C produced between the disk surface and the ABS 43 because of
the rotation of the magnetic disk 16. When the HDD is operated, the
ABS 43 of the slider 42 faces the disk surface, maintaining a space
from the disk surface. In this state, recording data is read from
the magnetic disk 16 by the reading head 54, and further, data is
written to the magnetic disk 16 by the recording head 58.
[0056] In writing data, as shown in FIG. 3, direct current is
supplied from the power source 74 to the main magnetic pole 60, the
STO 65 and the trailing shield 62. Thus, a high-frequency magnetic
field (microwave) is produced from the STO 65. This high-frequency
magnetic field is applied to the magnetic recording layer 103 of
the magnetic disk 16. Alternating current is supplied from the
power source 80 to the recording coil 64, and thus, the main
magnetic pole 60 is excited by the recording coil 64. From the main
magnetic pole 60, a recording magnetic field is perpendicularly
applied to the recording layer 103 of the magnetic disk 16
immediately under the main magnetic pole 60. In this manner, data
is recorded in the magnetic recording layer 103 with a desired
track width. By superimposing a high-frequency magnetic filed on
the recording magnetic field, the magnetization inversion of the
magnetic recording layer 103 is stimulated. Thus, it is possible to
perform magnetic recording of a high-magnetic-anisotropy energy. By
supplying current from the main magnetic pole 60 to the trailing
shield 62, the disorder in the magnetic domain of the main magnetic
pole 60 can be eliminated. Thus, an efficient magnetic path can be
obtained. The magnetic filed produced from the apical end of the
main magnetic pole 60 is enhanced.
[0057] In the above embodiment, in the recording head 58, the
magnetic layer 82 formed of a high-magnetic-permeability material
is provided on the pole surface facing the STO 65. Further, in the
recording head 58, the granular magnetic layer formed of the
nonmagnetic layer 84 containing magnetic microparticles is provided
so as to be in contact with an external side of the magnetic layer
82 different from the STO 65 side. In this manner, the spin wave
produced from the STO 65 is blocked by the nonmagnetic layer
(granular magnetic layer) 84, and is not transferred beyond the
nonmagnetic layer 84. Thus, the rotation of magnetization (spin
wave) on the opposite surface facing the STO 65 in the magnetic
core is restricted. Thus, the rotation of magnetization of the STO
65 becomes excellent as it is not disturbed by the above spin wave.
In this manner, the oscillation magnetic field of the STO 65 is
increased. At the same time, it is possible to prevent blurring of
writing in the recording magnetic field, the recording saturation
on the trailing shield 62 side and the fringe magnetic field by
providing the magnetic layer 82 formed of a
high-magnetic-permeability material on the surface (leading-side
end surface 62b) of the trailing shield 62 facing the STO 65.
[0058] By providing the granular magnetic layer (nonmagnetic layer
84), the transmission of spin wave is restricted, and thus, the
effect of magnetic field assist of the high-frequency-assisted
element (STO 65) is increased. In this manner, the recording
performance of the recording head is enhanced, thereby improving
the recording density. Further, the track density can be improved
by the effect of prevention of recording saturation or the effect
of fringe prevention because of the magnetic layer 82 provided on
the opposite surface of the trailing shield 62 facing the STO 65.
Thus, the areal density of the HDD can be improved.
[0059] FIG. 8 shows the distribution of magnetic field in the head
travel direction in the track center and in the vicinity
immediately under the write gap with respect to the magnetic head
of the present embodiment, a conventional magnetic head which does
not comprise a magnetic layer or a nonmagnetic layer (comparative
example 1) and a magnetic head without an STO (comparative example
2). This figure shows that the maximum magnetic field strength is
increased in the magnetic head comprising an STO in comparative
example 1 in comparison with the magnetic head which does not have
an STO in comparative example 2. However, in the magnetic head of
comparative example 1, since a spin wave is produced in the
trailing shield 62, the magnetic field gradient is decreased, and
thus, the recording resolution is reduced. The magnetic head of the
present embodiment produces no loss in the magnetic field rotation
in the trailing shield 62. Thus, both the magnetic field strength
and the magnetic field gradient are increased.
[0060] FIG. 9 shows the relationship between the maximum magnetic
field strength and the magnetic field gradient on the trailing side
of the main magnetic pole when the magnetic heads of the present
embodiment and comparative examples 1 and 2 are used. This figure
shows that both the magnetic field strength and the magnetic field
gradient are increased in the magnetic head of the present
embodiment in comparison with the magnetic heads of comparative
examples 1 and 2.
[0061] FIG. 10 shows the relationship between distance d from the
track center of the magnetic head to the nonmagnetic layer 84 in
FIG. 7 and the angle of rotation of magnetization from the film
surface of the STO 65. When the nonmagnetic layer 84 is provided
near the STO 65, in other words, when distance d is less, the spin
wave is not transferred to the trailing shield 62. Thus, the
rotation of magnetization of the STO 65 is large around the axis
perpendicular to the film surface. In this manner, the STO 65
exhibits good oscillation. When distance d is increased, and the
nonmagnetic layer 84 is located remote from the STO 65, a spin wave
is produced, and thus, the angle of rotation of magnetization of
the STO 65 is decreased. The STO 65 does not exhibit good
oscillation. In the example shown in FIG. 10, the state of
oscillation of the STO 65 is good when distance d is in the range
of 20 to 80 nm.
[0062] FIG. 11 shows the relationship between distance d and the
maximum magnetic field strength of the magnetic head. When distance
d is less (for example, less than or equal to 20 nm), in other
words, when the nonmagnetic layer 84 in which magnetic
microparticles are dispersed is provided on the leading-side end
surface 62b of the trailing shield 62 facing the STO 65, the amount
of magnetic field intrusion from the main magnetic pole 60 to the
trailing shield 62 is decreased. Thus, the magnetic field strength
is decreased.
[0063] FIG. 10 and FIG. 11 show that it is possible to obtain both
a sufficient magnetic field strength and a sufficient angle of
rotation of the STO by providing the nonmagnetic layer 84 outside
the side edge of the STO 65 on the leading-side end surface 62b,
specifically, by setting distance d to approximately 20 to 80 nm in
the examples of the figures. Distance d is preferably greater than
the distance (for example, 20 nm) from the track center to the side
edge of the STO 65, and less than approximately the four times (80
nm) the distance from the track center to the side edge of the STO
65. The distance (MH-SH) from the upper edge of the STO 65 to the
nonmagnetic layer 84 in the height direction is preferably set to,
for example, approximately 5 to 60 nm.
[0064] FIG. 12 shows the relationship between the concentration (%;
contained amount) of magnetic microparticles in the nonmagnetic
layer 84 and the angle of oscillatory rotation of the STO 65 when
distance d from the track center is 20 nm and 60 nm. FIG. 13 shows
the relationship between the concentration (%; contained amount) of
magnetic microparticles in the nonmagnetic layer 84 and the maximum
magnetic field strength of the magnetic head when distance d from
the track center is 20 nm.
[0065] FIG. 12 shows that, either when distance d is 20 nm or 60
nm, the angle of oscillatory rotation of the STO 65 is increased as
the concentration of magnetic microparticles is decreased, and
further, the angle of oscillatory rotation is less at 30.degree.
with a concentration over approximately 50%. FIG. 13 shows that the
magnetic field strength is the greatest when the concentration of
magnetic microparticles is in the range of approximately 5 to 25%.
When the concentration exceeds 40%, the magnetic field strength is
decreased. In consideration of the above factors, to obtain both a
large angle of oscillatory rotation and a high magnetic field
strength, the concentration of magnetic microparticles in the
nonmagnetic layer 84 is preferably approximately 5 to 25%, and
further preferably approximately 10 to 20%.
[0066] As explained above, in the HDD and the magnetic head in the
present embodiment, the nonmagnetic layer (granular magnetic layer)
containing magnetic microparticles is provided outside the magnetic
layer facing the STO. With this structure, the spin wave in the
trailing shield 62 is produced only near the write gap surface
(leading-side end surface) of the trailing shield 62 and is not
transferred to the deep side of the trailing shield 62. Thus, the
rotation of magnetization of the oscillation layer of the STO 65 is
not affected by the spin wave, and thus, an excellent rotation of
magnetization can be obtained. The recording magnetic field
produced from the main magnetic pole 60 can prevent the
magnetization saturation of the trailing shield 62 and secure a
sufficient magnetic field gradient, using the magnetic layer 82
which is formed of a high-magnetic-permeability material and is
provided on the opposite surface of the magnetic core facing the
STO 65. In this manner, the recording line density can be
improved.
[0067] In the above manner, the present embodiment can provide a
magnetic recording head realizing stable high-frequency assist and
high recording density, and a disk device comprising the magnetic
recording head.
[0068] The following is a description of magnetic recording heads
of HDDs according to alternative embodiments. In the following
description of the alternative embodiments, like reference numbers
are used to designate the same elements as those of the first
embodiment, and a detailed description thereof is omitted or
simplified. Elements different from those of the first embodiment
are mainly explained in detail.
Second Embodiment
[0069] FIG. 14 is an enlarged perspective view schematically
showing the apical end portion of a magnetic recording head in an
HDD according to a second embodiment. FIG. 15 is a plan view
showing the apical end portion of the magnetic recording head when
viewed from the ABS side. As shown in FIG. 14 and FIG. 15, a
magnetic layer 82 formed of a high-magnetic-permeability material
is provided on a leading-side end surface 62b of a trailing shield
62, and faces an STO 65. Further, a nonmagnetic layer 84 is
provided outside the magnetic layer 82 in the leading-side end
portion of the trailing shield 62. Magnetic microparticles are
dispersed in the entire part of the nonmagnetic layer 84
substantially uniformly. In the second embodiment, the nonmagnetic
layer 84 is allocated on the entire surface of the leading-side end
surface 62b of the trailing shield 62 in the width direction
excluding the portion of the magnetic layer 82 facing the STO
65.
[0070] In the second embodiment, the other structures of the HDD
are the same as those of the first embodiment.
Third Embodiment
[0071] FIG. 16 is an enlarged perspective view schematically
showing the apical end portion of a magnetic recording head in an
HDD according to a third embodiment. FIG. 17 is a plan view showing
the apical end portion of the magnetic recording head when viewed
from the ABS side. As shown in FIG. 16 and FIG. 17, a magnetic
layer 82 formed of a high-magnetic-permeability material is
provided on a leading-side end surface 62b of a trailing shield 62,
and faces an STO 65. Further, in the leading-side end portion of
the trailing shield 62, a pair of nonmagnetic layers 84a and 84b in
which magnetic microparticles are dispersed substantially uniformly
are provided outside the magnetic layer 82, here, on both sides of
the magnetic layer 82 in the track width direction. The back
surface side of the magnetic layer 82 is connected to the trailing
shield 62. The magnetic layer 82 is formed integrally with the
trailing shield 62.
[0072] The pair of nonmagnetic layers 84a and 84b are exposed to
the leading-side end surface 62b and the upper surface of the
trailing shield 62 and the ABS. Distance d from the track center S
to the nonmagnetic layers 84a and 84b is set so as to be greater
than half the width of the STO 65 in the track width direction, and
is set to, for example, approximately 20 to 80 nm.
[0073] In the third embodiment, the other structures of the HDD are
the same as those of the first embodiment.
Fourth Embodiment
[0074] FIG. 18 is an enlarged perspective view schematically
showing the apical end portion of a magnetic recording head in an
HDD according to a fourth embodiment. FIG. 19 is a plan view
showing the apical end portion of the magnetic recording head when
viewed from the ABS side. As shown in FIG. 18 and FIG. 19, in the
present embodiment, the magnetic core of the magnetic recording
head comprises a pair of side shields 86a and 86b formed of a soft
magnetic material on both sides of a main magnetic pole 60 in the
track width direction across intervening gaps. The side shields 86a
and 86b are formed integrally with a trailing shield 62, and
protrude from a leading-side end surface 62b of the trailing shield
62 to the leading side.
[0075] Magnetic layers 82a and 82b formed of a
high-magnetic-permeability material are respectively provided on
the opposite surfaces of the side shields 86a and 86b facing an STO
65, and face the STO 65. Further, in the side shields 86a and 86b,
nonmagnetic layers 84a and 84b are provided outside the magnetic
layers 82a and 82b relative to the STO 65, here, on the back
surfaces of the magnetic layers 82a and 82b on sides opposite to
the STO 65 side. Magnetic microparticles are dispersed in the
nonmagnetic layers 84a and 84b substantially uniformly. The
contained amount (concentration) of magnetic microparticles is the
same as that of the first embodiment.
[0076] The pair of nonmagnetic layers 84a and 84b are exposed to
the leading-side end surface and the upper surface of the side
shields 86a and 86b, and the ABS. Distance d from the track center
S to the nonmagnetic layers 84a and 84b is set so as to be greater
than half the width of the STO 65 in the track width direction, and
is set to, for example, approximately 60 to 80 nm.
[0077] In the fourth embodiment, the other structures of the HDD
are the same as those of the first embodiment.
Fifth Embodiment
[0078] FIG. 20 is an enlarged perspective view schematically
showing the apical end portion of a magnetic recording head in an
HDD according to a fifth embodiment. FIG. 21 is a plan view showing
the apical end portion of the magnetic recording head when viewed
from the ABS side. As shown in FIG. 20 and FIG. 21, in the present
embodiment, the magnetic core of the magnetic recording head
comprises a pair of side shields 86a and 86b formed of a soft
magnetic material on both sides of a main magnetic pole 60 in the
track width direction across intervening gaps. The side shields 86a
and 86b are formed integrally with a trailing shield 62, and
protrude from a leading-side end surface 62b of the trailing shield
62 to the leading side.
[0079] Magnetic layers 82, 82a and 82b comprise a
high-magnetic-permeability material, and are continuously formed on
the leading-side end surface 62b of the trailing shield 62, and the
opposite surfaces (facing an STO 65) of the side shields 86a, 86b
located on both sides of the STO 65 in the width direction. The
magnetic layers 82, 82a and 82b face the STO 65. Further, in the
trailing shield 62 and the side shields 86a and 86b, nonmagnetic
layers 84, 84a and 84b are continuously formed outside the magnetic
layers 82, 82a and 82b relative to an STO 65, here, on the back
surfaces of the magnetic layers 82, 82a and 82b on sides opposite
to the STO 65 side. Magnetic microparticles are dispersed in the
nonmagnetic layers 84, 84a and 84b substantially uniformly. The
contained amount (concentration) of magnetic microparticles is the
same as that of the first embodiment.
[0080] The nonmagnetic layers 84a and 84b are exposed to the
leading-side end surfaces and the upper surfaces of the side
shields 86a and 86b, respectively, and the ABS. The nonmagnetic
layer 84 is exposed to the upper surface of the trailing shield 62
and the ABS. Distance d from the track center S to the nonmagnetic
layers 84a and 84b is set so as to be greater than half the width
of the STO 65 in the track width direction, and is set to, for
example, approximately 60 to 80 nm. The distance from the STO 65 to
the nonmagnetic layer 84, in other words, the thickness of the
magnetic layer 82 is, for example, greater than or equal to 20
nm.
[0081] In the fifth embodiment, the other structures of the HDD are
the same as those of the first embodiment.
Sixth Embodiment
[0082] FIG. 22 is an enlarged perspective view schematically
showing the apical end portion of a magnetic recording head in an
HDD according to a sixth embodiment. In the present embodiment, in
the magnetic core of the magnetic recording head, an apical end
portion 60b of a main magnetic pole 60 is formed by a magnetic
layer 82 comprising a high-magnetic-permeability material, and
faces an STO 65. Further, in the main magnetic pole 60, a
nonmagnetic layer 84 is provided outside the magnetic layer 82
relative to the STO 65, here, in a middle portion of the tapered
portion of the main magnetic pole 60. Magnetic microparticles are
dispersed in the nonmagnetic layer 84 substantially uniformly. The
contained amount (concentration) of magnetic microparticles is the
same as that of the first embodiment. In the present embodiment,
the nonmagnetic layer 84 is provided parallel to the ABS, and is
formed over the entire width and the entire thickness of the main
magnetic pole 60. Further, the nonmagnetic layer 84 is away from
the upper surface of the STO 65 by approximately 20 to 60 nm.
[0083] In the sixth embodiment, the other structures of the HDD are
the same as those of the first embodiment.
[0084] In the second to sixth embodiments, an effect similar to
that of the first embodiment can be obtained. Specifically, in
addition to the first embodiment, in the second to sixth
embodiments, it is possible to restrict the rotation of
magnetization (spin wave) in the trailing shield 62, the
side-shields 86a and 86b and/or the STO-facing surface of the main
magnetic pole 60, using the nonmagnetic layers 84, 84a and 84b in
which magnetic microparticles are dispersed. Thus, the rotation of
magnetization of the STO 65 can be excellent. As a result, an
effect of magnetic field assist applied to the magnetic disks from
the STO 65 is increased. By improvement in the recording
performance, the high recording density can be realized.
[0085] While certain embodiments have been described, these
embodiments have been presented by way of example only, and are not
intended to limit the scope of the inventions. Indeed, the novel
embodiments described herein may be embodied in a variety of other
forms; furthermore, various omissions, substitutions and changes in
the form of the embodiments described herein may be made without
departing from the spirit of the inventions. The accompanying
claims and their equivalents are intended to cover such forms or
modifications as would fall within the scope and spirit of the
inventions.
[0086] For example, the sixth embodiment may be combined with any
of the first to fifth embodiments. A nonmagnetic layer containing
magnetic microparticles may be provided in both the trailing shield
and the main magnetic pole. Alternatively, a nonmagnetic layer
containing magnetic microparticles may be provided in both the side
shield and the main magnetic pole. A nonmagnetic layer containing
magnetic microparticles may be provided in the following three
elements: the trailing shield; the side shield; and the main
magnetic pole.
[0087] The materials and shapes of the magnetic layers and the
nonmagnetic layers are not limited the above embodiments, and may
be changed depending on the need. The materials, shapes and sizes
of elements constituting the head portion of the magnetic head may
be changed depending on the need. In the magnetic disk device, the
number of magnetic disks and magnetic heads may be increased or
decreased depending on the need. The size of magnetic disks may be
selected in various ways.
* * * * *