Claims
- 1. A magnetooptical recording method comprising the steps of:
- (a) providing a disk-shaped magnetooptical recording medium having a perpendicular magnetic anisotropy film of a multilayered structure including a fist layer as a recording layer and a second layer as a reference layer;
- (b) rotating said medium;
- (c) applying an initial field to said medium at a first position so that a direction of magnetization of said second layer is aligned in advance along a first direction perpendicular to said film;
- (d) applying to said medium at a second position a bias field of lower intensity than said initial field;
- (e) applying to said medium a jointing field which continuously varies in intensity along a rotating direction of said medium from he initial field at said first position to the bias field at said second position; and
- (f) radiating an energy beam which is modulated in accordance with binary data to be recorded onto said medium at said second position;
- whereby when an intensity of the modulated energy beam is at high level, one of a bit having magnetization in the first direction and a bit having magnetization in a second direction opposite to the first direction is formed in said first layer, and when the intensity of the modulated energy beam is al low level, the other bit is formed in said first layer.
- 2. A method according to claim 1, wherein when the intensity of the energy beam is at high level, the first direction of magnetization of said second layer is reversed to the second direction by the bias field, and said one bit is formed in said first layer by the reversed magnetization, and when the intensity of the energy beam is at low level, said other bit is formed in said first layer by magnetization in the first direction of said second layer.
- 3. A method according to claim 1, wherein the energy beam consists of adjacent leading and trailing beams, the leading beam has a substantially constant intensity, and the trailing beam is modulated in accordance with the binary data between said high level and base level lower than said low level.
- 4. A method according to claim 1, wherein the recording medium provided is formed so as to include a substrate with said perpendicular magnetic anisotropy film thereon;
- said first layer comprising a transition metal-heavy rare earth alloy which is heavy rare earth rich and has a compensation temperature between a room temperature and a Curie temperature, said second layer comprising a transition metal-heavy rare earth alloy which is heavy rare earth rich and has a compensation temperature between a room temperature and a Curie temperature, and said medium satisfying following Formula (1):
- T.sub.R <Tcomp.1<T.sub.C1 .apprxeq.T.sub.L .apprxeq.Tcomp.2<T.sub.C2 .apprxeq.T.sub.H ( 1)
- and satisfying at the room temperature following Formulas: ##EQU16## where T.sub.R : room temperature
- T.sub.comp.1 : compensation temperature of first layer
- T.sub.comp.2 : compensation temperature of second layer
- T.sub.C1 : Curie temperature of first layer
- T.sub.C2 : Curie temperature of second layer
- T.sub.L : temperature of recording medium when low-level laser beam is radiated
- T.sub.H : temperature of recording medium when high-level laser beam is radiated
- H.sub.C1 : coercivity of first layer
- H.sub.C2 : coercivity of second layer
- M.sub.S1 : saturation magnetization of first layer
- M.sub.S2 : saturation magnetization of second layer
- t.sub.1 : thickness of first layer
- t.sub.2 : thickness of second layer
- .sigma..sub.w : interface wall energy
- Hini.: initial field
- Hb: bias field.
- 5. A method according to claim 1, wherein the recording medium provided is formed so as to include a substrate with said perpendicular magnetic anisotropy film thereon;
- said first layer comprising a transition metal-heavy rare earth alloy which is heavy rare earth rich and does not have a compensation temperature between a room temperature and a Curie temperature, said second layer comprising a transition metal-heavy rare earth alloy which is heavy rare earth rich and has a compensation temperature between the room temperature and the Curie temperature, and said medium satisfying following Formula (1):
- T.sub.R <T.sub.C1 .apprxeq.T.sub.L .apprxeq.T.sub.comp.2 <T.sub.C2 .apprxeq.T.sub.H ( 2)
- and satisfying at the room temperature following Formulas: ##EQU17## where T.sub.R : room temperature
- T.sub.comp.2 : compensation temperature of second layer
- T.sub.C1 : Curie temperature of first layer
- T.sub.C2 : Curie temperature of second layer
- T.sub.L : temperature of recording medium when low-level laser beam is radiated
- T.sub.H : temperature of recording medium when high-level laser beam is radiated
- H.sub.C1 : coercivity of first layer
- H.sub.C2 : coercivity of second layer
- M.sub.S1 : saturation magnetization of first layer
- M.sub.S2 : saturation magnetization of second layer
- t.sub.1 : thickness of first layer
- t.sub.2 : thickness of second layer
- .sigma..sub.w : interface wall energy
- Hini.: initial field
- Hb: bias field.
- 6. A method according to claim 1, wherein the recording medium provided is formed so as to include a substrate with said perpendicular magnetic anisotropy film thereon:
- said first layer comprising a transition metal-heavy rare earth alloy which is heavy rare earth rich and does not have a compensation temperature between a room temperature and a Curie temperature, said second layer comprising a transition metal-heavy rare earth alloy which is heavy rare earth rich and has a compensation temperature between the room temperature and the Curie temperature, and said medium satisfying following Formula (1):
- T.sub.R <T.sub.C1 .apprxeq.T.sub.L .apprxeq.T.sub.comp.2 <T.sub.C2 .apprxeq.T.sub.H ( 1)
- and satisfying at the room temperature following Formulas: ##EQU18## where T.sub.R : room temperature
- T.sub.comp.2 : compensation temperature of second layer
- T.sub.C1 : Curie temperature of first layer
- T.sub.C2 : Curie temperature of second layer
- T.sub.L : temperature of recording medium when low-level laser beam is radiated
- T.sub.H : temperature of recording medium when high-level laser beam is radiated
- H.sub.C1 : coercivity of firm layer
- H.sub.C2 : coercivity of second layer
- M.sub.S1 : saturation magnetization of first layer
- M.sub.S2 : saturation magnetization of second layer
- t.sub.1 : thickness of first layer
- t.sub.2 : thickness of second layer
- .sigma..sub.w : interface wall energy
- Hini.: initial field
- Hb: bias field.
- 7. A magnetooptical recording apparatus comprising:
- means for rotating a disk-shaped magnetooptical recording medium including a perpendicular magnetic anisotropy film;
- means for applying an initial field tb said medium at a first position;
- means for applying to said medium at a second position a bias field of lower intensity than said initial field;
- means for applying to said medium a jointing field which continuously varies in intensity from the initial field at sam first position to the bias field at said second position in a rotating direction of said medium;
- means for supplying, onto said medium at said second position, an energy beam for locally heating said medium; and
- means for modulating an intensity of the energy beam in accordance with binary data to be recorded between high level for providing a temperature suitable for forming in said perpendicular magnetic anisotropy film a bit having magnetization in a first direction perpendicular to the surface of said medium and low level for providing a temperature suitable for forming in said perpendicular magnetic anisotropy film a bit having magnetization in a second direction opposite to the first direction.
- 8. An apparatus according to claim 7, wherein said energy beam supplying means supplies adjacent leading and trailing beams, the leading beam has a substantially constant intensity, and the trailing beam is modulated in accordance with the binary data between said high level and base level lower than said low level.
- 9. An apparatus according to claim 7, wherein said recording medium comprises a substrate having said perpendicular magnetic anisotropy film thereon, said film having a multilayered structure including first and second layers;
- said first layer comprising a transition metal-heavy rare earth alloy which is heavy rare earth rich and has a compensation temperature between a room temperature and a Curie temperature, said second layer comprising a transition metal-heavy rare earth alloy which is heavy rare earth rich and has a compensation temperature between a room temperature and a Curie temperature, and said medium satisfying following Formula (1):
- T.sub.R <T.sub.comp.1 <T.sub.C1 .apprxeq.T.sub.L .apprxeq.T.sub.comp.2 <T.sub.C2 .apprxeq.T.sub.H ( 1)
- and satisfying at the room temperature following Formulas: ##EQU19## where T.sub.R : room temperature
- T.sub.comp.1 : compensation temperature of first layer
- T.sub.comp.1 : compensation temperature Of second layer
- T.sub.C1 : Curie temperature of first layer
- T.sub.C2 : Curie temperature of second layer
- T.sub.L : temperature of recording medium when low-level laser beam is radiated
- T.sub.H : temperature of recording medium when high-level laser beam is radiated
- H.sub.C1 : coercivity of first layer
- H.sub.C2 : coercivity of second layer
- M.sub.S1 : saturation magnetization of first layer
- M.sub.S2 : saturation magnetization of second layer
- t.sub.3 : thickness of first layer
- t.sub.2 : thickness of second layer
- .sigma..sub.w : interface wall energy
- Hini.: initial field
- Hb: bias field.
- 10. An apparatus according to claim 7, wherein said recording medium comprises a substrate having said perpendicular magnetic anisotropy film thereon, said film having a multilayered structure including first and second layers;
- said first layer comprising a transition metal-heavy rare earth alloy which is heavy rare earth rich and does not have a compensation temperature between a room temperature and a Curie temperature, said second layer comprising a transition metal-heavy rare earth alloy which is heavy rare earth rich and has a compensation temperature between the room temperature and the Curie temperature, and said medium satisfying following Formula (1):
- T.sub.R <T.sub.C1.apprxeq.T.sub.L .apprxeq.T.sub.comp.2 <T.sub.C2 .apprxeq.T.sub.H ( 1)
- and satisfying at the room temperature following Formulas: ##EQU20## where T.sub.R : room temperature
- T.sub.comp.2 : compensation temperature of second layer
- T.sub.C1 : Curie temperature of first layer
- T.sub.C2 : Curie temperature of second layer
- T.sub.L : temperature of recording medium when low-level laser beam is radiated
- T.sub.H : temperature of recording medium when high-level laser beam is radiated
- H.sub.C1 : coercivity of first layer
- H.sub.C2 : coercivity of second layer
- M.sub.S1 : saturation magnetization of first layer
- M.sub.S2 : saturation magnetization of second layer
- t.sub.1 : thickness of first layer
- t.sub.2 : thickness of second layer
- .sigma..sub.w : interface wall energy
- Hini.: initial field
- Hb: bias field.
- 11. An apparatus according to claim 7, wherein said recording medium comprises a substrate having said perpendicular magnetic anisotropy film thereon, said film having a multilayered structure including first and second layers;
- said first layer comprising a transition metal-heavy rare earth alloy which is heavy rare earth rich and does not have a compensation temperature between a room temperature and a Curie temperature, said second layer comprising a transition metal-heavy rare earth alloy which is heavy rare earth rich and has a compensation temperature between the room temperature and the Curie temperature, and said medium satisfying following Formula (1):
- T.sub.R <T.sub.C1 .apprxeq.T.sub.L .apprxeq.T.sub.comp.2 <T.sub.C2 .apprxeq.T.sub.H ( 1)
- and satisfying at the room temperature following Formulas: ##EQU21## where T.sub.R : room temperature
- T.sub.comp.2 : compensation temperature of second layer
- T.sub.C1 : Curie temperature of first layer
- T.sub.C2 : Curie temperature of second layer
- T.sub.L : temperature of recording medium when low-level laser beam is radiated
- T.sub.H : temperature of recording medium when high-level laser beam is radiated
- H.sub.C1 : coercivity of first layer
- H.sub.C2 : coercivity of second layer
- M.sub.S1 : saturation magnetization of first layer
- M.sub.S2 : saturation magnetization of second layer
- t.sub.1 : thickness of first layer
- t.sub.2 : thickness of second layer
- .sigma..sub.w : interface wall energy
- Hini.: initial field
- Hb: bias field. .Iadd.
- 12. A magnetooptical recording apparatus comprising:
- means for rotating a disk-shaped magnetooptical recording medium including a perpendicular magnetic anisotropy film;
- means for applying an initial field to said medium at a first position;
- means for applying to said medium at a second position a bias field of lower intensity than said initial field;
- said initial field applying means and said bias field applying means cooperatively applying to said medium a jointing field which continuously varies in intensity from the initial field at said first position to the bias field at said second position in a rotating direction of said medium;
- means for supplying, onto said medium at said second position, an energy beam for locally heating said medium; and
- means for modulating an intensity of the energy beam in accordance with binary data to be recorded between high level for providing a temperature suitable for forming in said perpendicular magnetic anisotropy film a bit having magnetization in a first direction perpendicular to the surface of said medium and low level for providing a temperature suitable for forming in said perpendicular magnetic anisotropy film a bit having magnetization in a second direction opposite to the first direction. .Iaddend..Iadd.
- 13. A magnetooptical recording apparatus comprising:
- means for rotating a disk-shaped magnetooptical recording medium including a perpendicular magnetic anisotropy film;
- means for applying to said medium a continuous field continuously varying in intensity from an initial field at a first position to a bias field of lower intensity than the initial field at a second position in a rotating direction of said medium;
- means for supplying, onto said medium at said second position, an energy beam for locally heating said medium; and
- means for modulating an intensity of the energy beam in accordance with binary data to be recorded between high level for providing a temperature suitable for forming in said perpendicular magnetic anisotropy film a bit having a magnetization in a first direction perpendicular to the surface of said medium and low level for providing a temperature suitable for forming in said perpendicular magnetic anisotropy film a bit having magnetization in a second direction opposite to the first direction. .Iaddend..Iadd.14. A magnetooptical recording apparatus comprising:
- means for rotating a disk-shaped magnetooptical recording medium including a perpendicular magnetic anisotropy film;
- means for applying to said medium a continuous field continuously decreasing in intensity from a first position to a second position in a rotating direction of said medium;
- means for supplying, onto said medium at said second position, an energy beam for locally heating said medium; and
- means for modulating an intensity of the energy beam in accordance with binary data to be recorded between high level for providing a temperature suitable for forming in said perpendicular magnetic anisotropy film a bit having magnetization in a first direction perpendicular to the surface of said medium and low level for providing a temperature suitable for forming in said perpendicular magnetic anisotropy film a bit having magnetization in a second direction opposite to the first direction. .Iaddend.
Priority Claims (1)
Number |
Date |
Country |
Kind |
62-120642 |
May 1987 |
JPX |
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Parent Case Info
This is a continuation of application Ser. No. 471,524 filed Jan. 29, 1990, now abandoned, which is a division of application Ser. No. 192,764 filed May 10, 1988, now U.S. Pat. No. 4,910,622, issued Mar. 20, 1990.
US Referenced Citations (3)
Number |
Name |
Date |
Kind |
4660190 |
Fujii et al. |
Apr 1987 |
|
4672594 |
Kato et al. |
Jun 1987 |
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4855975 |
Akasaka et al. |
Aug 1989 |
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Divisions (1)
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Number |
Date |
Country |
Parent |
192764 |
May 1988 |
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Continuations (1)
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Number |
Date |
Country |
Parent |
471524 |
Jan 1990 |
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Reissues (1)
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Number |
Date |
Country |
Parent |
668376 |
Mar 1991 |
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