JP2004005975A - Information recording medium and method for recording/reading information using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To realize an information recording medium and a recording/reading method for realizing high density recording with a pitch smaller than a light wavelength. <P>SOLUTION: In the information recording medium and the recording/reading method for recording information by using an energy beam such as a laser beam 7 and an electron beam, and a magnetic field, an energy beam and a magnetic field are made to emit or applied to the recording medium while the position of the energy beam and the magnetic field on the recording medium is moved, wherein bubbles movable in the direction of a recording track are generated without the emission of at least one type of an energy beam, such as air bubbles, liquid bubbles and magnetic foams (magnetic bubble) and the size of the bubbles becomes larger by the emission of reading energy beam and magnetic field. Bubbles are generated or expanded to be recorded, and after the emission or application of the energy beam and the magnetic field is finished, the bubbles are reduced and stored. Bubbles at a place to which the reading energy beam and magnetic field are made to emit or applied are expanded so that the existence and positions of the bubbles can be detected for reading. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
[Industrial applications]
According to the present invention, analog signals such as video and audio are FM-modulated by recording energy such as laser light, electron beam and current, and digital information such as electronic computer data and facsimile signals and digital audio signals are converted. And a thin film for recording information that can be recorded in real time.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in optical memories such as optical disks and optical cards, reading is performed by detecting the intensity of reflected light from a recording medium (including the effect of changing the intensity due to interference due to a phase difference) with one photodetector, The above-described photodetector is used to detect the intensity distribution of the reflected light or to detect the deflection surface of the reflected light by the amount of light transmitted through the analyzer, but the resolution at which information is read depends on the wavelength of the light. It is extremely difficult to read information recorded at a pitch equal to or less than the wavelength. In order to overcome this difficulty, there is also known a method of providing an aperture on a recording medium for restricting a read signal (Japanese Patent Laid-Open No. 3-93056) and a method of enlarging a recording mark. Japanese Patent Laid-Open Publication No. 1-143041 discloses an enlarged read method of a recording mark, in which the magnetic domain of the read layer recorded together with the information holding layer is cut off the magnetic constraint from the information holding layer at the time of reading. A method of performing the enlargement is shown.
[0003]
[Problems to be solved by the invention]
SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide an information recording medium and an information recording / reading method which realize ultra-high-density recording at a pitch smaller than a limit determined by the wavelength of light, eliminating the above-mentioned problems of the prior art.
[0004]
In the conventional method of reading a micro mark by enlarging a magnetic domain, in order to enlarge only a part of a magnetic domain row corresponding to recording information on a reading layer, a magnetic domain expansion range is written next to the magnetic domain. Is limited to a range that does not contact the magnetic domain. In addition, since the distance between the enlarged magnetic domain and the adjacent magnetic domain is reduced, crosstalk at the time of reading becomes a problem.
[0005]
[Means for Solving the Problems]
In order to achieve the above object, an information recording medium, information recording / reading method, information recording / reading method, information reading method, and information recording method according to the present invention, in which information is recorded or read by an energy beam of a laser beam / electron beam or a magnetic field. In the information recording device and the information reading device, the first aspect of the present invention is characterized in that (1) an information recording medium for recording and reading information by an energy beam of laser light / electron beam or a magnetic field; It is at least one selected from bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles), and produces bubbles whose size changes due to an intensity gradient, a direction change, or a temperature gradient of an energy beam or a magnetic field. This is a recording medium for information that is increased by irradiation or application of a reading energy beam or a magnetic field, and is reduced after irradiation or application.
[0006]
(2) In (1), it is preferable that the size of the bubble be reduced and the center position of the bubble be moved in the direction opposite to the traveling direction of the energy beam spot after the irradiation or application is completed.
[0007]
(3) In (1), there is a repulsive force and / or attractive force between the bubbles, so that when the bubbles expand and / or contract, the bubbles already present in the vicinity maintain the ratio of the distance between each other. It is preferable to move.
[0008]
(4) In (1) and (3), it is preferable that the foam has a repulsive force between the foams and, when the foam expands, the foams already existing in the vicinity move so as to keep substantially in contact with each other. .
[0009]
(5) In (1), it is preferable to provide a bubble storage portion for holding many or large bubbles in a part of the recording track.
[0010]
According to a second aspect of the present invention, there is provided (6) a recording medium in which magnetic bubbles are generated in an information recording medium for recording or reading information by an energy beam of laser light / electron beam or a magnetic field, wherein the non-magnetic layer At least a first magnetic layer on the energy beam incident side and a second magnetic layer far from the incident side with respect to the energy beam. ₀ , The Curie temperatures of the first and second magnetic layers are respectively set to Tc ₁ And Tc ₂ And Tc ₁ > Tc ₂ > T ₀ In the information recording medium, the thickness of the second magnetic layer is larger than the thickness of the first magnetic layer.
[0011]
(7) In (6), a third magnetic layer is provided adjacent to the first magnetic layer, and a fourth magnetic layer is provided adjacent to the third magnetic layer. Curie temperature of the magnetic layer of No. 4 was set to Tc ₃ And Tc ₄ And the exchange force that the first magnetic film receives from the fourth magnetic film through the third magnetic film is Heexc. ₁₄ The exchange force that the fourth magnetic film receives from the first magnetic film through the third magnetic film is Heexc. ₄₁ , Tc ₁ , Tc ₄ > Tc ₃ > T ₀ And the temperature of the recording medium is T, Tc ₃ >T> T ₀ Hc at least in part of the temperature range satisfying ₄ -Hexc ₄₁ > Hc ₁ -Hexc ₁₄ Satisfies the condition of ₁ -Hexc ₁₄ > Hc ₄ -Hexc ₄₁ It is preferable to satisfy the following condition.
[0012]
According to a third aspect of the present invention, there is provided (8) a recording medium in which magnetic bubbles are generated in an information recording medium for recording or reading information by an energy beam of laser light / electron beam or a magnetic field, wherein the non-magnetic layer A first magnetic layer on the energy beam incident side and a second magnetic layer far from the incident side with the ₀ , The Curie temperature of the first magnetic layer is set to Tc ₁ , The compensation temperature of the second magnetic layer is set to Tcomp ₂ And Tc ₁ > Tcomp ₂ > T ₀ In the information recording medium, the thickness of the second magnetic layer is larger than the thickness of the first magnetic layer.
[0013]
(9) In (8), a third magnetic layer is provided adjacent to the first magnetic layer, and a fourth magnetic layer is provided adjacent to the third magnetic layer. Curie temperature of the magnetic layer of No. 4 was set to Tc ₃ And Tc ₄ And the exchange force that the first magnetic film receives from the fourth magnetic film through the third magnetic film is Heexc. ₁₄ The exchange force that the fourth magnetic film receives from the first magnetic film through the third magnetic film is Heexc. ₄₁ , Tc ₁ , Tc ₄ > Tc ₃ > T ₀ And the temperature of the recording medium is T, Tc ₃ >T> T ₀ Hc at least in part of the temperature range satisfying ₄ -Hexc ₄₁ > Hc ₁ -Hexc ₁₄ Hc at lower temperatures ₁ -Hexc ₁₄ > Hc ₄ -Hexc ₄₁ It is preferable to satisfy the following condition.
[0014]
(10) In (8), Hc ₁ -Hexc ₁₄ = Hc ₄ -Hexc ₄₁ Hc when ₁ -Hexc ₁₄ Is a negative value. That is, the direction is preferably such that the recording magnetic domain of the magnetic layer 1 is reduced.
[0015]
A feature of the fourth invention is that (11) the magnetic bubbles are transferred from the first magnetic layer of the recording medium to another magnetic layer immediately after recording, and the magnetic bubbles are transferred from the other magnetic layer to the first magnetic layer immediately after reading. The method for recording and reading information to be transferred to the magnetic layer.
[0016]
(12) In (11), it is preferable to apply an external magnetic field in the direction opposite to the magnetization direction of the magnetic bubbles of the magnetic layer 1 during recording.
[0017]
(13) In (11), a laminated film having at least first, third, fourth, and second magnetic layers in the order of lamination and having a nonmagnetic layer between the fourth and second magnetic layers is formed. And the Curie temperature of the magnetic layer is set to Tc ₁ , Tc ₃ , Tc ₄ , Tc ₂ Tc ₁ , Tc ₄ > Tc ₃ > Tc ₂ Using a recording medium that satisfies the relationship of ₁ Tc from below 30 ° C ₄ It is preferable to set the temperature up to 30 ° C.
[0018]
(14) In (13), it is preferable to apply an external magnetic field in the direction opposite to the magnetization direction of the magnetic bubbles of the magnetic layer 1 during recording.
[0019]
(15) In (14), the absolute value of the external magnetic field is Tc ₃ Hc at lower temperature ₄ -Hexc ₄₁ = Hc ₁ -Hexc ₁₄ Hc when ₄ -Hexc ₄₁ Is preferably larger than the absolute value of
[0020]
(16) In (11), a laminated film having at least first, third, fourth, and second four magnetic layers in the lamination order and having a nonmagnetic layer between the fourth and second magnetic layers is formed. And the Curie temperature of the magnetic layer is set to Tc ₁ , Tc ₃ , Tc ₄ , Tc ₂ Tc ₁ , Tc ₄ > Tc ₃ > Tc ₂ Using a recording medium that satisfies the relationship of ₃ Tc from below 30 ° C ₁ It is preferable to set the temperature up to 30 ° C. below.
[0021]
(17) In (16), a laminated film having at least first, third, fourth, and second magnetic layers in the lamination order and having a non-magnetic layer between the fourth and second magnetic layers is formed. And the Curie temperature of the magnetic layer is set to Tc ₁ , Tc ₃ , Tc ₄ , Tc ₂ Tc ₁ , Tc ₄ > Tc ₃ > Tc ₂ The exchange force that the first magnetic film receives from the fourth magnetic film through the third magnetic film using a recording medium satisfying the relationship ₁₄ The exchange force that the fourth magnetic film receives from the first magnetic film through the third magnetic film is Heexc. ₄₁ , The absolute value of the external magnetic field at the time of reading is Tc ₃ Hc at lower temperature ₄ -Hexc ₄₁ = Hc ₁ -Hexc ₁₄ Hc when ₄ -Hexc ₄₁ Is preferably smaller than the absolute value of
[0022]
(18) In (17), a laminated film having at least first, third, fourth, and second magnetic layers in the lamination order and having a nonmagnetic layer between the fourth and second magnetic layers is formed. And the Curie temperature of the magnetic layer is set to Tc ₁ , Tc ₃ , Tc ₄ , Tc ₂ Tc ₁ , Tc ₄ > Tc ₃ > Tc ₂ When the magnetic field applied to the magnetic layer 4 at the time of reading is lower than the maximum temperature of the magnetic layer 4 at the time of reading, the coercive force Hc of the magnetic layer 4 is used. ₄ Preferably smaller.
[0023]
According to a fifth aspect of the present invention, there is provided (19) a recording medium for recording or reading information by an energy beam of laser light / electron beam or a magnetic field, and is selected from bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles). At least one type of bubble that changes its size due to the intensity gradient, direction change, or temperature gradient of the energy beam or magnetic field, and the size of the bubble increases when irradiated or applied with the recording or reading energy beam or magnetic field. In a method for recording and reading information using a recording medium for information that is reduced after irradiation or application, at least one type selected from among bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles), and an intensity gradient of an energy beam or a magnetic field. Uses a recording medium for information in which bubbles whose size changes due to changes in direction and temperature or a temperature gradient are used. 1 and in the recording and reading method information associated with the 0 of the item.
[0024]
According to a sixth aspect of the present invention, there is provided (20) a recording medium for recording or reading information by an energy beam of laser light / electron beam or a magnetic field, and is selected from bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles). At least one type of bubble that changes its size due to the intensity gradient, direction change, or temperature gradient of the energy beam or magnetic field, and the size of the bubble increases when irradiated or applied with the recording or reading energy beam or magnetic field. In a method for recording and reading information using a recording medium for information that is reduced after irradiation or application, at least one type selected from among bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles), and an intensity gradient of an energy beam or a magnetic field. The size of the bubble changes due to changes in direction or temperature gradient, and the center position moves. After the irradiation or application, the center position of the bubble is reduced by moving in the direction opposite to the direction of travel of the energy beam spot, and the size and position of the information are fixed. In the method of recording / reading information, at least one type selected from bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles), and information in which bubbles whose size changes due to an intensity gradient, a direction change, or a temperature gradient of an energy beam or a magnetic field are generated. There are two types of bubbles described above, and there is a method for recording and reading information in which the types of bubbles correspond to digital signals 1 and 0.
[0025]
A feature of the seventh invention is that (21) a recording medium for recording or reading information by an energy beam of laser light / electron beam or a magnetic field is selected from bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles). At least one type of bubble that changes its size due to the intensity gradient, direction change, or temperature gradient of the energy beam or magnetic field, and the size of the bubble increases when irradiated or applied with the recording or reading energy beam or magnetic field. In a method for recording and reading information using a recording medium for information that is reduced after irradiation or application, at least one type selected from among bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles), and an intensity gradient of an energy beam or a magnetic field. Uses a recording medium for information in which bubbles whose size changes due to changes in direction or temperature gradient are used. There are two types of bubbles, and the boundary between different types of bubbles In recording and reading method information associated with the first Ijitaru signal.
[0026]
According to an eighth aspect of the present invention, there is provided (22) a recording medium for recording or reading information by an energy beam of a laser beam / electron beam or a magnetic field, and is selected from bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles). At least one type of bubble that changes its size due to the intensity gradient, direction change, or temperature gradient of the energy beam or magnetic field, and the size of the bubble increases when irradiated or applied with the recording or reading energy beam or magnetic field. In a method for recording and reading information using a recording medium for information that is reduced after irradiation or application, at least one type selected from among bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles), and an intensity gradient of an energy beam or a magnetic field. Use a recording medium for information in which bubbles whose size changes due to changes in direction or temperature or temperature gradient are used. There are two or more types of bubbles, and information of three or more values is recorded. Or the recording and reading method of reading information.
[0027]
A ninth aspect of the present invention is characterized in that (23) a recording medium for recording or reading information by an energy beam of laser light / electron beam or a magnetic field is selected from bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles). At least one type of bubble that changes its size due to the intensity gradient, direction change, or temperature gradient of the energy beam or magnetic field, and the size of the bubble increases when irradiated or applied with the recording or reading energy beam or magnetic field. In a method for recording and reading information using a recording medium for information that is reduced after irradiation or application, at least one type selected from among bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles), and an intensity gradient of an energy beam or a magnetic field. Use a recording medium of information that generates bubbles whose size changes due to changes in direction or temperature gradient. During even read, in recording and reading method information to empower the recording start end direction.
[0028]
According to a tenth aspect of the present invention, there is provided (24) a recording medium for recording or reading information by using an energy beam of laser light / electron beam or a magnetic field, and is selected from bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles). At least one type of bubble that changes its size due to the intensity gradient, direction change, or temperature gradient of the energy beam or magnetic field, and the size of the bubble increases when irradiated or applied with the recording or reading energy beam or magnetic field. In a method of reading information using a recording medium for information that is reduced after irradiation or application, at least one selected from bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles), and the intensity gradient or direction of an energy beam or a magnetic field Uses a recording medium for information that generates bubbles whose size changes due to changes or temperature gradients, without having to read the information, just waiting on the truck. When only it is to reduce the laser power from the time of reading, in the method of reading information such expansion or movement of the bubbles does not occur.
[0029]
A feature of the eleventh invention is (25) at least one kind selected from bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles), and bubbles whose size changes due to an intensity gradient, a direction change, or a temperature gradient of an energy beam or a magnetic field. Using an information recording medium in which recording occurs, recording is performed on an end portion of a recording track or a sector with a length of 2 to 10 times the length of the irradiation or application area of the energy beam or magnetic field on the recording medium in the track direction. There is a method of recording information provided with no area.
[0030]
A twelfth aspect of the present invention is characterized in that (26) in an information recording apparatus for recording information by an energy beam of a laser light / electron beam or a magnetic field, the energy beam or the magnetic field is irradiated while moving the position on the recording medium. A means for generating and expanding at least one kind of bubble selected from bubbles, liquid bubbles, and magnetic bubbles (magnetic bubbles) in the recording medium by applying and / or applying the recording, and moving the central position of the bubbles to store the bubbles. Information recording device.
[0031]
The thirteenth aspect of the present invention is characterized in that (27) in an information recording apparatus for recording information by an energy beam of laser light / electron beam or a magnetic field, means for converging the energy beam on the recording medium; Means for relative movement of the focused spot of the energy beam, means for converting the intensity, phase, distribution, or plane of polarization of the reflected light from the recording medium into an electric signal, and a reference for determining the recording start position on the recording medium. After reading a signal from the recording medium, the timing at which a drive pulse for recording is applied to the energy beam source is determined at a point in time after a certain time has passed since the center of the energy beam spot passed the position where the recording point should be stored. Means for adjusting the intensity of the energy beam at the determined irradiation timing and means for performing recording on the recording medium. Apparatus is in.
[0032]
According to a fourteenth aspect of the present invention, there is provided (28) in an information reading device for reading information by using an energy beam of a laser light / electron beam or a magnetic field, irradiating an energy beam or a magnetic field while moving a position on a recording medium. Means for expanding the bubble by applying and / or applying it and moving the center position, and detecting the presence of the bubble by converting the intensity, phase, distribution and change of the deflection surface of the reflected light from the recording medium into an electric signal. And an information reading device having means for performing reading.
[0033]
A fifteenth aspect of the present invention is characterized in that (29) in an information reading device for reading information by an energy beam of a laser light / electron beam or a magnetic field, a means for focusing an energy beam on a recording medium; Means for relatively moving the focused spot of the beam, and converting the intensity, phase, distribution, and plane of polarization of the reflected light from the recording medium into an electric signal, so that the center of the energy beam spot is located at the recording point stored on the recording medium. An information reading apparatus includes means for detecting a change in a reproduction signal voltage indicating the existence of a recording point earlier than a point when the recording point passes the center position.
[0034]
Furthermore, by enlarging and transferring only the magnetic domains to be read from the information holding layer at the time of reading to the reading layer, the expansion range of the magnetic domains is not limited, and there is no crosstalk at the time of reading. Enlarged reading may be performed to enable reading of minute magnetic domains. In order to realize the above operation, the present invention has a structure in which a reading layer is provided in addition to a layer for recording information. For the readout layer, for example, a RE-TM alloy or garnet, which is a perpendicular magnetization film having a soft magnetic property with a coercive force of 0.2 T or less, is used. Here, RE is a rare earth element, and TM is one or more elements selected from Fe, Co, and Ni. The thickness of the readout layer is from 20 nm to 100 nm, and a layer for adjusting an exchange magnetic field or a leakage magnetic field from the recording layer may be provided between the recording layer and the readout layer. A memory layer or a memory layer and a switching layer existing on at least one of the memory layer and the read layer may be added between the recording layer and the read layer.
[0035]
The enlargement ratio of the magnetic domain at the time of reading is the same as in the first embodiment, and is preferably in the range of 1.5 to 10 times.
[0036]
When the reading light is pulsed light, it is preferable that the reading light be pulsed light of a constant frequency (may be changed on the inner and outer circumferences of the disk).
[0037]
[Action]
When the recording medium is irradiated with the recording energy beam, bubbles are generated in a portion of the recording film on the recording track. In the case of a combination of a recording medium and an energy beam and / or a magnetic field in which bubbles are increased by irradiation of a recording energy beam or application of a magnetic field, the bubbles are at least in the track direction (half direction in the case of a disk) after the irradiation or application. Depending on the type of recording medium, the image is also reduced and stored in a direction perpendicular to the track. In order for bubble reduction to occur, it is necessary to move the portion between bubbles, but this is a recording medium where apparent attraction acts between bubbles and bubbles, and near the recording start point on the recording track If the movement is prevented from occurring, the center position of the bubble moves in the direction opposite to the direction of movement of the energy beam or the magnetic field relative to the medium, and is stored with high density. Further, in the case of a recording medium in which the center position of the bubble moves in the direction opposite to the moving direction of the energy beam or the magnetic field due to the gradient of the temperature or the magnetic field, the attractive force between the bubbles is not required. In the case of performing magneto-optical recording, as shown in FIG. 3, an auxiliary magnetic layer is provided on a side opposite to the light incident side of the magnetic layer 1 which is a recording layer via a layer mainly composed of ZnS which is a dielectric layer. Providing the magnetic layer 2 made of TbCo is effective. For example, in the case of the auxiliary magnetic layer having a lower Curie point than the recording layer, as shown in FIG. 3, the region where the auxiliary magnetic layer exceeds the Curie point is in a direction opposite to the light spot traveling direction than the region where the magneto-optical recording film exceeds the Curie point. Because of the delay, when the temperature of the irradiated portion begins to decrease after the end of the recording pulse, the area where the magneto-optical recording layer (magnetic layer 1) exceeds the Curie point becomes small, and the area where the auxiliary magnetic layer exceeds the Curie point is reduced. The mark is strongly moved in the direction opposite to the traveling direction of the light spot. When the reading energy beam is irradiated, the bubbles near the place being irradiated expand, so that the size becomes suitable for reading and a large reading signal is obtained. After recording, if the magnetic domain is transferred to a memory layer (magnetic layer 4) made of TbFeCo adjacent to the recording layer (magnetic layer 1), the memory layer can be enlarged or reduced at the time of reading from the recording layer. This is preferable because the magnetic domain can be returned to the original state by performing reverse transfer from the recording mark, so that the position or size of the recording mark does not change. In the case of bubbles or magnetic bubbles in which the bubbles can move due to the interaction between the bubbles and the foam or between the bubbles and the substance between the bubbles even when the bubbles expand outside the application range of the energy beam irradiation or the magnetic field, at least the energy beam And bubbles stored in the direction of travel of the magnetic field are pushed forward. However, since the bubbles that have been read out are reduced, the extruded distance is at most 10 times the size of the readout energy beam or magnetic field in the track direction on the recording medium. Therefore, the area where recording is not performed by irradiating or applying an energy beam or a magnetic field has a size ranging from twice the size of the read energy beam or the magnetic field in the track direction on the recording medium to 10 times the maximum. Alternatively, there is no problem if it exists at the end of the sector.
[0038]
【Example】
[Example 1]
First, a ZnS-SiO2 is formed on the surface of an optical disk substrate on which a U-shaped tracking groove or a pit representing a track or sector address is transferred on the surface of a glass substrate with an ultraviolet curable resin. ₂ A lower protective layer made of the mixture and having a thickness of about 100 nm was formed by a vacuum deposition method. Next, a low molecular weight paraffinic hydrocarbon was vacuum-deposited thereon. Next, this disk was heated to 60 ° C. to evaporate and flow the paraffin between the tracking grooves so that liquid paraffin was present only in the grooves. Next, an Sb-Bi layer, which is both a light absorption layer and a reflection layer, was vacuum deposited to a thickness of about 100 nm. Further, a protective layer of SiO ₂ The layers were vacuum deposited. Finally, the above-mentioned SiO ₂ The layer side was bonded to another glass substrate.
[0039]
The optical disk formed as described above was irradiated with a weak laser beam to track the tracking groove, and the end of each sector of each track was searched. By particularly intensifying the laser beam at that portion, the paraffin was evaporated by the heat generated in the Sb-Bi layer, and the ultraviolet curing resin was deformed by the pressure to form the bubble reservoir 5 as shown in FIG. In the bubble reservoir, the decomposition product gas of the impurities in the paraffin stayed even after cooling.
[0040]
Set the optical disk manufactured as described above on a modified optical disk device so that the laser power can be adjusted using a commercially available optical disk device, and increase the laser power according to the digital signal to be recorded while performing autofocus and tracking with weak laser light. Information was recorded by weakening. In the user data recording area of the sector to be recorded, when the laser beam 1 is intensified at the "1" portion of the digital signal, heat generated in the Sb-Bi layer generates decomposition gas from impurities in the paraffin, and FIG. Large bubbles 2 as shown in FIG. When the light spot passes by, the temperature decreases and the air bubbles are reduced, and the air bubbles 3 are stored as air bubbles 3 having a constant size. Straight lines visible above and below the bubbles in the figure indicate the inclined surfaces of the grooves formed on the substrate surface. At the beginning of the user data recording area in the sector, since the paraffin is blocked by a step, no air bubble enters the header area in which addresses and the like are represented as pits on the substrate surface. When recording is continued in this manner, the recorded information is stored in a reduced size, so that an extremely large amount of information can be recorded. Although the liquid paraffin is pushed forward by the amount of the stored bubbles, it can be solved by filling the previously formed bubble reservoir with the liquid paraffin. However, the increased pressure as a whole helps to reduce the stored bubbles. Instead of newly generating bubbles, fine seeds of bubbles may be present in the recording film from the beginning and expand them. In order to prevent the bubbles at the recording end from being pushed out by the bubbles due to expansion at the time of reading, a non-recording area of about 5 times the diameter of the light beam spot was provided at the recording end. However, this area is naturally generated when the bubble formed at the end of recording contracts after the end of recording. The size of this region is preferably in the range of 2 to 10 times the diameter of the light beam spot.
[0041]
At the time of reading information, when a laser beam having a constant power lower than that of the pulse at the time of recording is irradiated, as shown in FIG. Since the light spot expands, the information can be read by sufficiently decomposing the light spot. When the temperature decreases due to the passage of the light spot, the bubbles become bubbles 8 reduced to the original size and are stored again. At this time, the volume of the liquid between the bubbles does not increase, but slightly decreases, and the vicinity of the recording start portion is blocked and does not move. The gravitational force moves to keep the original high-density preservation state. The enlargement ratio of the bubble by the reading light was about twice in this embodiment, but the higher the magnification, the higher the recording density. However, if the air bubbles during storage are too small, the storage stability and the position stability deteriorate, so that a range of 1.5 to 10 times is appropriate.
[0042]
In the present embodiment, the same light beam is used for recording and reading, and the power for recording is increased.However, at the time of recording, if a light beam having a different wavelength and a high bubble forming ability is used, the power can be made the same, The power at the time of recording can be reduced.
[0043]
In this embodiment, an example in which the size of the bubble is substantially constant has been described. However, the recording may be performed by a pit edge method in which the length or intensity of the recording pulse is changed to change the size of the stored bubble.
[0044]
The recording density is further improved by using a recording medium in which the distance between the bubbles is enlarged or reduced at the same ratio as the size of the bubbles.
[0045]
SiO ₂ A recording medium in which the formation order of the layer and the Sb-Bi layer was reversed was usable although the recording sensitivity was slightly lowered.
[0046]
In the case of using a recording film in which the film thickness of the recording track portion increases due to the formation of bubbles, the bubble storage is not required, and the recording film may be solid except at the periphery of the laser beam irradiation portion. However, when the bubbles move little by little in the direction opposite to the direction of travel of the laser beam by reading, the header of each sector is also recorded by bubbles instead of providing irregularities on the substrate surface. It is preferable that the information on the entire track be moved little by little for each readout in one round.
[0047]
In this embodiment, the case of bubbles is described.However, if a recording medium that generates another liquid that does not mix with the original liquid by light irradiation is used, another bubble-like liquid, that is, a liquid bubble can be formed and recorded. it can.
[0048]
As an equivalent to a bubble, an excited state or the like which is stable and movable in a solid may be used.
[0049]
[Example 2]
First, a silicon nitride layer, which is an enhancement layer, is formed on the surface of a polycarbonate substrate for an optical disk, which is formed by an injection molding method and has a U-shaped tracking groove on its surface and pits indicating track and sector addresses and synchronization signals. A Pt / Co multilayer alternating multilayer film known as a short-wavelength magneto-optical recording film was formed to a thickness of about 30 nm as a magneto-optical recording layer. Subsequently, a silicon nitride layer as an intermediate layer was formed to a thickness of 30 nm, and an Al layer was formed thereon. ₉₇ Ti ₃ The layer was formed to a thickness of 50 nm. Another identical optical disk was prepared and, after initial magnetization in one direction, bonded together with an ultraviolet-curing resin with the Al-Ti layer side inside.
[0050]
The recording film of the optical disk produced as described above is set on a commercially available optical disk device using a semiconductor laser having a wavelength of 780 nm as a light source and modified so that the laser power can be adjusted, and autofocusing and tracking are performed with weak laser light. While applying a magnetic field in the recording direction from an electromagnet arranged on the opposite side of the optical head across the disk, information to be stored on the disk was recorded.
[0051]
As shown in FIG. 2A, in the user data recording area of the sector to be recorded, when the laser beam 9 is intensified at the "1" part of the digital signal, the area 10 exceeding the large Curie point due to heat generation of the recording film. There has occurred. In this area, the temperature decreases as the light spot passes, and the area decreases and the center moves slightly in the direction opposite to the moving direction of the light spot due to a temperature gradient, and is stored as a magnetic bubble (magnetic domain 11). Note that the straight line that looks like sandwiching the reduced magnetic domain from above and below in the figure is the inclined portion of the groove (or vice versa) on the substrate surface. Since the magnetic bubble magnetic domain has a large coercive force at room temperature, its size does not change and does not move at about 200 Oe which is a recording magnetic field of a normal magneto-optical disk. In this way, the presence or absence of a magnetic domain is recorded in correspondence with the digital signals 1 and 0. When recording is continued in this manner, the recorded information is stored in a reduced size, so that an extremely large amount of information can be recorded. In order to strengthen the movement of the reduced recording mark in the direction opposite to the light spot traveling direction and further increase the recording density, as shown in FIG. On the side opposite to the light incident side, a layer (29) containing ZnS as a non-magnetic (dielectric) layer as a main component, and Tb as an auxiliary magnetic layer ₂₀ Co ₈₀ It is effective to provide the magnetic layer 2 (30) composed of (composition estimated from the area ratio of the sputtering target at the time of film formation). At this time, the thickness of each layer is, for example, about 70 nm for the lower protective layer, 30 nm for the magnetic layer 1, 200 mm for the non-magnetic layer, and about 200 nm for the magnetic layer 2. It is preferably at least 5 times thicker. In this case, the intermediate layer and the Al-Ti layer may not be provided on the magnetic layer 2, but the presence of the intermediate layer and the Al-Ti layer results in better heat radiation and better recording characteristics. The magnetization of the auxiliary magnetic layer is aligned in one direction. In the case of the auxiliary magnetic layer having a lower Curie point than the recording layer, as shown in the lower part of FIG. 3, the region where the auxiliary magnetic layer exceeds the Curie point is opposite to the light spot traveling direction than the region where the magneto-optical recording film exceeds the Curie point. Lag in the direction. For this reason, when the temperature of the irradiated portion begins to decrease after the end of the recording pulse, the area where the magneto-optical recording layer (magnetic layer 1) exceeds the Curie point becomes smaller, and at the same time, the area where the auxiliary magnetic layer exceeds the Curie point becomes smaller. The mark is strongly moved in the direction opposite to the traveling direction of the light spot. At the next recording pulse, the area of the auxiliary magnetic layer beyond the Curie point expands again, and at the same time, when the temperature of the magneto-optical recording layer rises, a new recording mark starts to be formed and expands. If the auxiliary layer has a magnetic characteristic such that the isotherm corresponding to the compensation temperature is not the Curie point but a curve outside the lower part of FIG. 3, the change rate of the magnetic field acting on the magnetic domain of the magnetic layer 1 can be reduced. There is an advantage that it is easy to increase the size. In this case, the Curie point of the auxiliary layer is higher than that of the recording layer, the room temperature is To, and the Curie points of the magnetic layers 1 and 2 are Tc. ₁ , Tc ₂ And the compensation temperature of the magnetic layer 2 is Tcomp ₂ Tc ₂ > Tc ₁ > Tcomp ₂ > To, but Tc ₁ And Tc ₂ The relationship can be used in reverse.
[0052]
At the time of reading information, as shown in FIG. 2B, when a laser beam 14 having a lower power than the pulse at the time of recording is irradiated, only the magnetic domains 15, 16, and 17 near the portion irradiated with the laser beam are emitted. Since the temperature rises and expands, the information can be read after being sufficiently decomposed by the light spot. When the temperature decreases due to the passage of the light spot, the magnetic domain is reduced to its original size, and the center moves slightly in the direction opposite to the moving direction of the light spot due to a temperature gradient and a magnetic field gradient, and is stored again. Therefore, the magnetic domains are kept densely packed toward the recording start end. After recording, as shown in FIG. 4, Tb close to the recording layer 33 (magnetic layer 1) ₂₅ Fe ₆₅ Co ₁₀ When the magnetic domain is transferred to the memory layer 35 (magnetic layer 4) made of the magnetic layer 4, even if the recording point is enlarged or reduced at the time of reading from the recording layer, the magnetic domain can be reversely transferred from the memory layer to restore the magnetic domain. This is preferable because the size does not change. The transfer may be performed immediately after recording to immediately before reading. In order to realize this transfer and to make recording / reading successful, for example, Tb is placed between the memory layer and the recording layer. ₂₀ Fe ₆₀ Co ₁₀ Al ₁₀ It is preferable to provide a switching layer 34 (magnetic layer 3) made of. Without the magnetic layer 3, the expansion and contraction of the magnetic domains becomes somewhat difficult, but transfer is possible. 4, reference numerals 32, 36, and 37 denote a substrate, a dielectric layer, and an auxiliary magnetic layer respectively corresponding to 31, 29, and 30 in FIG. The temperature dependence of the difference between the coercive force Hc and the exchange force Heexc of these layers is preferably, for example, as shown in FIG. In this case, examples of preferable thicknesses of the magnetic layer 1, the magnetic layer 2, the magnetic layer 3, and the magnetic layer 4 are 30 nm, 200 nm, 10 nm, and 30 nm, respectively. At the time of reading, at least the high-temperature regions of the magnetic layers 1, 3, and 4 have a temperature intermediate between the Curie point of the magnetic layer 3 and the Curie point of the magnetic layer 4. Since the magnetic domain exceeds the Curie point of the magnetic layer 3, the magnetic domain of the magnetic layer 1 can be read in an enlarged manner regardless of the magnetic domain of the magnetic layer 4. At the time of reading, the temperature is lower than at the time of recording. Therefore, the expansion of the magnetic domain is realized by changing the intensity or direction of the external magnetic field by the coil from that at the time of recording. The reading light irradiation may be continuous, but is preferably in a pulse form. When a coil capable of high-speed magnetic field modulation is used, it is preferable to change the magnetic field at a high speed. Due to the temperature gradient and the strength gradient of the magnetic field, the expansion of the magnetic domain occurs in a direction opposite to the relative movement of the light spot with respect to the recording medium. That is, the center of the magnetic domain moves in the direction opposite to the relative motion and then contracts. In the case of pulsed light or a pulsed magnetic field, this reduction tends to occur. Therefore, there is no possibility that the magnetic domain that has not been read yet is affected. As a result, the top or bottom of the reproduction signal voltage indicating the existence of the recording point before the point at which the center of the light spot passes the center position of the recording point stored on the recording medium reduces the intensity of the reflected light from the recording medium. Detected by the detecting detector. The advance time t of this detection preferably satisfies the condition 0.2 B / A <t <B / A, where Am / s is the linear velocity at the time of reading the recording track and Bm is the half-value diameter of the light spot. It is more preferable to satisfy the condition of 0.3B / A <t <0.7B / A. When this condition is not satisfied, the recording points are not sufficiently expanded, and a sufficient reproduction signal intensity cannot be obtained. When the temperature falls below the Curie point of the magnetic layer 3 due to the passage of the light spot, the magnetic layer 1 and the magnetic layer 4 are exchange-coupled again, and Hc at the point where the two curves in FIG. ₁ -Hexc ₁₄ For example, when a magnetic field corresponding to the position indicated by an arrow in the positive direction (positive in the direction of magnetization at the recording point of the magnetic layer 1) is applied, the magnetic domain pattern stored in the magnetic layer 4 becomes The magnetic domain is transferred to the magnetic layer 1 in which the magnetic domains are disturbed by reading.
[0053]
If a combination of the magnetic layer 1 and the magnetic layer 4 having magnetic properties such that the exchange force becomes small at a high temperature is used, the magnetic layer 3 as a switching layer can be omitted.
[0054]
On the other hand, as another method, after transfer from the recording layer to the memory layer (magnetic layer 4), the Gd adjacent to the memory layer is further transferred. ₂₅ Fe ₆₅ Co ₁₀ May be transferred to the readout layer (magnetic layer 5), and then enlarged and read out by the readout layer. After the reading, the recording marks are transferred from the non-read layer to the read layer. The preferred thickness of the magnetic layer 5 is 50 nm.
[0055]
When the magnetic properties of the auxiliary magnetic layer are as shown in FIG. 6, at the time of reading, the isotherm at which the auxiliary (magnetic) layer has a compensation temperature is as shown by the outer curve at the bottom in FIG. When the magnetic properties of the auxiliary layer are given, the auxiliary layer strengthens the external magnetic field inside the isotherm and weakens it outside the isotherm, so that the expanded magnetic domain moves in the direction opposite to the movement direction of the light spot. help.
[0056]
When there is no need to read information, and only waiting on the track, it is better to lower the laser power than at the time of reading so that expansion and movement of the magnetic domain do not occur.
[0057]
When an external magnetic field having an intensity gradient in the track direction is applied at the time of recording and reading, the movement of the magnetic domain is further facilitated.
[0058]
The enlargement ratio of the magnetic domain at the time of reading is the same as in the first embodiment, and is preferably in the range of 1.5 to 10 times.
[0059]
When the reading light is pulsed light, it is preferable that the reading light be pulsed light of a constant frequency (may be changed on the inner and outer circumferences of the disk).
[0060]
When recording is performed on the multilayer film, the recording layer (magnetic layer 1) is heated by a laser beam to a temperature near the Curie point. At this time, since the magnetic layer 3 has already exceeded the Curie point, there is no restriction on the recording layer from other layers. When the area of the recording layer beyond the Curie point falls below the Curie point, it is magnetized in the opposite direction to that initially magnetized by the external magnetic field, the leakage magnetic field from other parts of the recording layer, and the bias layer. Recorded magnetic domains. The magnetic domains move in the direction opposite to the moving direction of the light spot by the action of the auxiliary layer while the size decreases as the temperature decreases. Therefore, after reading from the recording medium a timing signal serving as a reference for determining the recording start position on the recording medium, the above-described movement of the magnetic domain is predicted, and the position where the recording point should be stored is set at the center of the light spot. It is necessary to supply a drive pulse for recording to the light source after a lapse of a certain time after passing through. The above-mentioned fixed time t is defined as the time from when the center of the light spot passes through the center of the position where the target recording point is stored to when it reaches the center of the drive pulse for recording. If the linear velocity of the light spot is Cm / s and the half-value diameter of the light spot is Dm, it is preferable to satisfy the condition of 0.2D / C <t <3D / C, and the condition of 0.5D / C <t <D / C Is particularly preferable. If this condition is not satisfied, the reduction of the recording point is not sufficient, and it is difficult to perform high-density recording at 1.5 times or more the conventional size. When the temperature further drops below the Curie point of the magnetic layer 3, the magnetic layer 1 and the magnetic layer 4 are exchange-coupled, and the Hc at the point where the two curves in FIG. ₁ -Hexc ₁₄ The magnetic domain of the magnetic layer 1 is transferred to the magnetic layer 4 by applying a magnetic field corresponding to, for example, the position of the arrow in the negative direction (positive in the magnetization direction of the recording point of the magnetic layer 1). You.
[0061]
In this embodiment, an example in which the width of the recording pulse is fixed and the size of the magnetic domain is almost constant has been described. However, the pit edge type recording in which the length or strength of the recording pulse is changed to change the size of the magnetic domain to be stored is also performed. May be performed. Also, magnetic field modulation recording may be performed in which recording is performed by changing the direction of a magnetic field in accordance with an information signal while performing light irradiation with constant power or pulse-like power modulation. In this case, since the recording marks can be formed at a considerably high density in the track direction (circumferential direction of the disk), it is not always necessary to reduce and preserve the recording marks, and in fact, the boundaries of the magnetic domains at the time of recording are opposite to the light spot traveling directions. Since it is determined by the isotherm of the low temperature part in the direction, no significant reduction occurs. However, at the time of reading, a large reproduction signal can be obtained if the reading is performed in an enlarged manner as in this embodiment, and the profit is great.
[0062]
Further, a readout layer may be further provided on the light incident side of the magnetic layer 1. It is preferable that a switching layer having a lower Curie point than the layers on both sides is provided between the readout layer and the magnetic layer 1, but lamination becomes easier when the switching layer is omitted. Recording may be performed at a high density in the same manner as in the present embodiment, and reading may be performed by transferring the data from the recording layer to the reading layer for each magnetic domain.
[0063]
When transfer to another layer is not used, the position of each magnetic domain moves slightly and slightly in the direction opposite to the direction of travel of the light beam each time reading is performed. Instead of being provided on the substrate surface in the form of irregularities, the data is recorded on the recording film after the disk is produced, and the readout light is applied to one track even when one sector is read. It is better to be.
[0064]
In the method of this embodiment, it is of course possible to rewrite the recorded information, and it is possible to erase by applying an external magnetic field in the direction opposite to that during recording while irradiating a laser beam of constant power, and then re-recording. In addition, a light modulation overwrite method using a known exchange-coupling two-layer film is also applicable.
[0065]
Although the present embodiment has been described for the case of recording with light, the present invention can also be applied to the case of recording with an electron beam and also to the magnetic recording of a magnetic disk or the like if a recording medium whose magnetic domains expand when a magnetic field is applied is used.
[0066]
Each magnetic domain may be transferred to the readout layer immediately after recording. However, if a magnetic layer close to the readout layer known as the iriser method is provided so that magnetic domains close to the magnetic domain being read out are not transferred, the readout layer may be transferred. Is preferably expanded.
[0067]
If the reduction ratio at the time of recording or the enlargement ratio at the time of reading is not so large, the magnetic layer 2 or the magnetic layer 2 and the dielectric layer (nonmagnetic layer) adjacent thereto may be omitted. Therefore, the laminated structure that can be taken in the present invention is as follows.
[0068]
1. Auxiliary magnetic layer-dielectric layer-memory layer-switching layer-recording / reading layer (magnetic layer 1)
2. Auxiliary magnetic layer-dielectric layer-recording / reading layer (magnetic layer 1)
3. Auxiliary magnetic layer-dielectric layer-memory layer-switching layer-recording layer-switching layer-readout layer
4. Auxiliary magnetic layer-dielectric layer-memory layer-recording layer-switching layer-reading layer
5. Auxiliary magnetic layer-dielectric layer-memory layer-switching layer-recording layer-readout layer
6. Auxiliary magnetic layer-dielectric layer-memory layer-recording layer-readout layer
7. Auxiliary magnetic layer-dielectric layer-recording layer-switching layer-readout layer
8. Auxiliary magnetic layer-dielectric layer-recording layer-readout layer
9. The laminated structure of the above 1 to 8 without an auxiliary magnetic layer
10. The laminated structure of the above 1 to 8 without the auxiliary magnetic layer and the dielectric layer
On the leftmost layer of each of the above structures, a protective layer of an ultraviolet curable resin is usually provided. When a double-sided disk is used, the ultraviolet curable resin layer side is bonded to another disk.
[0069]
In addition to the above structures, the following structure in which the memory layer is moved between the recording layer and the reading layer may be used.
[0070]
11. Auxiliary magnetic layer-dielectric layer-memory layer-switching layer-recording layer-switching layer-readout layer
12. Auxiliary magnetic layer-dielectric layer-memory layer-switching layer-recording layer-readout layer
13. Auxiliary magnetic layer-dielectric layer-memory layer-recording layer-switching layer-reading layer
14． Auxiliary magnetic layer-dielectric layer-memory layer-recording layer-readout layer
15. The laminated structure of the above items 11 to 14 having no auxiliary magnetic layer
16. Laminated structure of above 11 to 14 without auxiliary magnetic layer and dielectric layer
The operation at the time of reading will be described with respect to the laminated structures 7 to 8 described above. First, the magnetic domains of the recording layer are transferred to the reading layer by irradiation with a reading laser beam, and the transferred magnetic domains are enlarged. Here, one laser beam can serve both as a function of causing transfer enlargement and a reading function, and transfer enlargement and reading can be operated with two laser beams. At the time of this reading, it is also possible to supplementarily apply a magnetic field from the outside. The reading laser beam sequentially follows the recording magnetic domains, so that reading of new magnetic domains may be repeated in order to overwrite the magnetic domains for which reading has been completed, or the magnetization direction of the reading layer may be recorded. After the magnetic domains are uniformly aligned by the initialization magnets disposed slightly above the medium, the magnetic domains may be transferred and enlarged and read with an interval sufficient to prevent mutual interference.
[0071]
When the reading of a new magnetic domain is repeated successively in such a manner as to overwrite the magnetic domain for which the reading has been completed, the transfer of the recording magnetic domain to the reading layer is performed by irradiating the reading beam 42 as shown in FIG. When the temperature of the recording layer 38 rises and the coercive force of the read layer decreases as compared with the leakage from the recording layer 39 and / or the exchange magnetic field, a nucleus 40 of magnetization reversal is generated in the read layer, and the magnetization direction of the recording layer is changed. 41 is transferred. The magnetization reversal region pushes the domain wall 43 to a certain region by the pressure of the domain wall or an external magnetic field. This utilizes the fact that the mobility of the domain wall of the readout layer changes as the temperature rises, and this enlarged range 44 extends along the outer edge of the temperature rise portion due to the irradiation of the read beam. This expansion is the same when the magnetization direction 45 of the readout layer coincides with the magnetization direction 46 of the recording layer, as shown in FIG. Expand along. This readout is particularly suitable for reading high-density recording due to miniaturization of marks, because the readout domain is expanded to about the same or larger than the readout beam diameter, thereby improving readout performance. The high-performance reading is possible without enlarging the minute magnetic domain recorded in the conventional optical system without largely changing the conventional optical system.
[0072]
[Example 3]
First, a silicon nitride layer, which is an enhancement layer, having a thickness of about 100 nm is formed on the surface of a polycarbonate substrate for an optical disk, which is formed by an injection molding method and has a U-shaped tracking groove or a pit representing a track sector address on the surface. Then, a Gd-Co layer as a recording layer was formed to a thickness of about 50 nm. Subsequently, a silicon nitride layer as an intermediate layer was formed to a thickness of 30 nm, and an Al-Ti layer was formed thereon to a thickness of 100 nm. Finally, the Al-Ti layer side was bonded to another polycarbonate substrate with an ultraviolet curable resin.
[0073]
First, the recording film of the optical disk manufactured as described above is erased by magnetizing it in one direction, then set to a modified optical disk device with a commercially available optical disk device so that the laser power can be adjusted. The information was recorded by increasing or decreasing the laser power according to the digital signal to be recorded, while applying a magnetic field in the recording direction from an electromagnet arranged on the opposite side of the optical head with the disk in between.
[0074]
As shown in FIG. 9A, in the user data recording area of the sector to be recorded, when the laser beam 9 is intensified at the "1" portion of the digital signal, a large magnetic field is generated due to light absorption and heat generation of the Gd-Co recording film. A bubble 19 has occurred. When the light spot passes by, the temperature of the magnetic bubble decreases, and the magnetic bubble is reduced and stored as a magnetic bubble 21 having a constant size. This magnetic bubble moves even at room temperature due to the magnetic field gradient and the approach of other magnetic bubbles. The straight lines above and below the magnetic bubble that has been reduced and stored are the slopes of the grooves on the substrate surface. At the beginning of the user data recording area of the sector, the magnetic bubble is fixed by the step, so that the magnetic bubble does not enter the header area where the address and the like are formed as pits on the substrate surface. There are two types of magnetic bubbles. When the recording laser power is slightly increased and the magnetic field is formed while changing the magnetic field sharply, an abnormal magnetic bubble 20 is formed. When the magnetic bubble is formed with a constant magnetic field and a lower recording laser power, a normal magnetic bubble 21 is formed. Therefore, the types of bubbles were recorded in correspondence with digital signals 1 and 0. When recording is continued in this manner, the recorded information is stored in a reduced size, so that an extremely large amount of information can be recorded. As in the first embodiment, a short area where no recording is performed is provided at the recording end. It is preferable to record by a signal modulation method in which the number of abnormal magnetic bubbles is smaller than the number of normal magnetic bubbles.
[0075]
At the time of reading information, as shown in FIG. 9B, when a laser beam 23 of a constant power lower than the pulse at the time of recording is irradiated, only the magnetic bubbles 24, 25, and 26 near the portion irradiated with the laser beam are emitted. Since the temperature rises and expands, the information can be read after being sufficiently decomposed by the light spot. When the light spot passes and the temperature drops, the magnetic bubbles are reduced to their original size and stored again. At this time, a magnetic field having an intensity gradient in the track direction is applied from the magnet to at least the bubble closest to the recording end portion, and at least at the time of reading, a force is applied to the recording start end portion, so that the magnetic bubble is , And keep a state of being densely packed in the direction of the recording start end. A magnetic field having an intensity gradient in the track direction is preferably applied also during recording. The magnification of the magnetic bubble at the time of reading is the same as that of the first embodiment, and is preferably in the range of 1.5 to 10 times. The expansion of the magnetic bubble may be performed not only by the temperature change but also by the change of the magnetic field. However, there is a problem that the expansion range becomes large and the recording density is apt to be reduced.
[0076]
In the present embodiment, an example has been described in which the width of the recording pulse is constant and the size of the magnetic bubble is substantially constant, but the length or intensity of the recording pulse is changed to change the size of the magnetic bubble to be stored. Recording may be performed.
[0077]
Multi-valued recording can also be performed by using an abnormal magnetic bubble, a normal magnetic bubble, a portion without a magnetic bubble, or a plurality of types of abnormal magnetic bubbles having different numbers of Bloch lines and a normal magnetic bubble.
[0078]
Although the present embodiment has been described for the case where recording is performed by light, the present invention can be applied to magnetic recording such as a magnetic disk if a recording medium in which magnetic bubbles expand when a magnetic field is applied is used.
[0079]
[Example 4]
As shown in FIG. 10, an ultraviolet curable resin was applied on a glass disk and grooves formed at a pitch of 1.6 μm were used as the substrate 48. The following films were formed thereon by sputtering. First, a silicon nitride film 49 was laminated with a thickness of 85 nm. Next, as the readout layer 50, Gd ₂₀ Tb ₂ Co ₇₈ Is 80 nm and the recording layer 51 has a Curie temperature of 170 ° C. Tb. ₂₀ Fe ₇₂ Co ₈ Each of the films was laminated to a thickness of 40 nm. Finally, to prevent the magnetic layer from being oxidized and corroded, a silicon nitride film 15 was formed to a thickness of 80 nm. Thus, the magneto-optical recording medium according to the present invention was completed. Further, as a comparative sample, a magneto-optical recording medium in which the readout layer 50 was removed from the above structure was manufactured. The magneto-optical recording medium thus completed is rotated at a speed of 2400 rpm, and a laser wavelength of 780 nm, a NA of 0.55, and a recording power P of 11 mw is set to 12 MHz at the innermost circumference (radius 30 mm) of the recording area. The signal was recorded, and reproduction was performed with a reading power of 2 mW. As a result, in the sample provided with the readout layer, continuous transfer enlargement was performed, and an increase in signal was observed.
[0080]
[Example 5]
As shown in FIG. 11, using a sample having the same structure as that of the fourth embodiment and recorded under the same conditions, reading is performed by reading out every four magnetic domains of the recording layer 54 using the initialization magnet 53. Was performed. The read beam 55 was irradiated as a pulse 56 having a power of 2 mW in synchronization with the recording magnetic domain. By performing enlarged reading on the reading layer 57 initialized by the initialization magnet 53 at intervals of three recording magnetic domain lengths, the read magnetic domains 58 do not interfere with each other even if they are enlarged. Stable reading can be performed at a distance. When one round is completed, the magnetic domain of the readout layer is erased by the initialization magnet, the read is performed by one recording magnetic domain, the pulse phase is shifted, and the reading of the next round is started. In this way, four rounds are repeated to complete the reading of one track. In this system, a signal increase beyond continuous reading was observed.
[0081]
【The invention's effect】
According to the above, the size of the recording point corresponding to the size of the light beam spot and the magnetic head can be obtained at the time of recording and reading, and can be made smaller at the time of storage. , An extremely large capacity memory can be realized.
[Brief description of the drawings]
FIG. 1 is a principle diagram of recording and reading in one embodiment of the present invention.
FIG. 2 is a principle diagram of recording and reading in another embodiment of the present invention.
FIG. 3 is a diagram illustrating the principle of reducing a recording mark and moving the recording mark in a direction opposite to a light spot advancing direction in one embodiment of the present invention.
FIG. 4 is a diagram of a laminated structure enabling transfer preservation in one embodiment of the present invention.
FIG. 5 is a diagram showing the temperature dependence of the exchange coupling force of each magnetic layer in one example of the present invention.
FIG. 6 is a schematic diagram of magnetic properties of an auxiliary magnetic layer according to one example of the present invention.
FIG. 7 is a diagram showing a reading principle in one embodiment of the present invention.
FIG. 8 is a diagram showing a reading principle in one embodiment of the present invention.
FIG. 9 is a principle diagram of recording and reading in another embodiment of the present invention.
FIG. 10 is a diagram showing a disk structure according to an embodiment of the present invention.
FIG. 11 is a diagram for explaining a reading principle in one embodiment of the present invention.
[Explanation of symbols]
1 light spot
2 formed bubbles
3 Reduced and stored air bubbles
4 Recording track
5 No air bubbles
6 Readout light spot
7 Bubbles during reading
8 Bubbles stored reduced
9 light spots
10 Magnetic bubbles formed
11 Magnetic bubbles stored in reduced size
12 recording tracks
13 Readout light spot
14 Magnetic bubble during reading
15, 16 Magnetic bubble slightly larger before and after magnetic bubble being read
17 Magnetic bubbles stored in reduced size
18 light spots
19 Magnetic bubbles formed
20 Anomalous magnetic bubbles stored in reduced size
21 Normal Magnetic Bubble Stored Reduced
22 recording tracks
23 Readout light spot
24 Magnetic bubble during reading
25,26 Magnetic bubble slightly larger before and after magnetic bubble being read
27 Magnetic Bubbles Reduced and Stored
28 Recording layer
29 Dielectric layer
30 Auxiliary magnetic layer
31 substrate
32 substrates
33 recording layer
34 Switching Layer
35 Memory Layer
36 Dielectric layer
37 Auxiliary magnetic layer
38 Reading layer
39 recording layer
40 nuclei of magnetization reversal
41 Magnetization direction of recording layer
42 Reading beam
43 Domain Wall
44 Expansion range
45 Magnetization direction of readout layer
46 Magnetization direction of recording layer
47 magnetized region
48 substrates
49 silicon nitride film
50 Reading layer
51 recording layer
52 silicon nitride film
53 Initializing magnet
54 recording layer
55 Reading Beam
56 Read beam power time profile
57 Reading Layer
58 Magnetic Domains Read

Claims (1)

In an information reading device for reading information by an energy beam of a laser beam / electron beam or a magnetic field, means for focusing the energy beam on a recording medium, means for relatively moving a focusing spot of the recording medium and the energy beam, Converts the intensity, phase, distribution, and polarization plane of the reflected light from the recording medium into an electric signal, and the energy point of the energy beam spot passes through the center position of the recording point stored on the recording medium earlier than the recording point. An information reading device, comprising: means for detecting a change in a reproduction signal voltage indicating the presence of a signal.

Images