NL8600379A - MAGNETO-OPTICAL REGISTRATION TOOL. - Google Patents

Description

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86.3015 / vdKl / mW -1-

Magneto-optical recording medium.

The invention relates to magneto-optical recording for writing, reading and erasing information with the aid of a laser beam, and not particularly to a magnetic recording medium with a low deterioration of the properties and a high durability.

Amorphous rare earth transition metal films that can form a relatively high Kerr rotation angle 91 are currently considered to be important recording materials for magneto-optical recording according to an erasable optical recording system. Deamorphic rare earth transition metal films can be classified into two major alloy groupings, that is, Co-based alloy films with the highest Co content, the writing mainly taking place using a compensation point, and Fe-based alloy films with the highest highest Fe content, with writing mainly using a Curie point.

Of these amorphous films, a relatively large Kerr rotation angle 9 ^ can be obtained in particular with Gd-Tb-Fe or Tb-Fe-Co amorphous films of Fe-based alloys, and research and development of these films of Fe -based alloys have been very strong so far (see, for example, British Patent 2,071,696 and Japanese Patent Application Laid-Open No. 58-73746).

However, these amorphous rare earth transition metal films have a low corrosion resistance, and when these films are made to reside in a particularly moist atmosphere without any protective film, these films are very quickly attacked to form pores.

So far, Al, Ni, etc. have been cited as elements that can increase corrosion resistance without any decrease in the Kerr rotation angle 9 ^ as an important reading factor (K. Aratani, T. Kobayashi and S.

Uchiyama: J. Appl. Phys. 5J, no. 8 (1985) 3903j M. Asano M. Kobayashi, K. Kawamura and S. Ohno: MRS Spring Meeting

Symposium D 6.5 (1985)).

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However, when the conventional amorphous films, including such alloy films, are subjected to repeated writing, reading and erasing, the carrier to noise ratio (C / N) of the reading by thermal hysteresis by laser beam irradiation gradually deteriorates. , or their properties gradually deteriorate due to oxidation, etc. even in atmospheric conditions. Therefore, there were problems with the life of the films. Particularly in the case of the Fe-based alloy systems, the Fe is present in large amount in addition to the rare earth elements, and therefore problems such as poor corrosion resistance and very short life of the films existed.

The present invention aims to provide a magneto-15 optical recording medium without any deterioration of the C / N ratio when reading, even when subjected to thermal hysteresis by laser beam irradiation, etc.

The present invention further aims to provide a magneto-optical recording medium without any deterioration of the C / N ratio when reading even when subjected to thermal hysteresis, and with excellent corrosion resistance,

These objects of the present invention can be achieved using an amorphous rare earth transition metal film, with a preferred magnetization axis in a direction perpendicular to the film surface, which as an additive element contains 0.5 to 10 atoms of at least one element selected from the group consisting of Er, Ho, 5fc, Ta, 30 Rh and W.

Of the amorphous rare earth transition metal films, the Fe-based alloy systems have a lot of Fe which has poor corrosion resistance, in addition to the rare earth elements, and it is therefore preferable to choose at least one of the elements Nb, Ta, and Rh from the said additive elements and add it to the Fe-based alloy systems, because Nb, Ta and Rh can significantly improve the corrosion resistance, as will be described below. Obviously, one of 40 of these additive elements, when also added to the Co-based alloy system which has a higher corrosion resistance than the Fe-based alloy system, can also be added to the Co-based alloy system. improve its corrosion resistance.

In the Co-based alloy system, the addition of at least one of the elements Ho, Nb and Rh is effective, but the addition of at least one of the elements Er, Ta and W is more effective, and in particular the addition of Ta is most effective.

The Fe-based alloy system is an alloy system of the following general formula: (Fel-xMx) 100-aRa wherein M is a transition metal other than Fe, R a rare earth element, and x is not greater than 0.5. In the present invention, at least one of these additive elements is added to the alloy system.

The Co-based alloy system is an alloy system of the general formula: (Co, M), nn R „1-xx 100-aa 20 in which M is a transition metal other than Co, R a rare earth element, and x is not greater than 0.5. In the present invention, at least one of said additive elements is added to this alloy system.

An alloy system represented by the general formula: ^ Co0.5Fe0.5 ^ 100-aRa is not one of the two alloy systems mentioned, but falls within the scope of the present invention, because the same effect as in the Co-based alloy system 30 can be obtained in this alloy system.

In the general formulas above, a is generally 15-45, preferably 18-30.

The principle of the present invention will be described in more detail below.

Generally, a criterion for the thermal stability of an amorphous alloy film is the crystallization temperature Tx, where Tx is the temperature at which an amorphous phase changes to a crystalline phase. In general, the higher Tx of an amorphous alloy film, the more stable the amorphous phase to a high temperature, and therefore * τ -4-, the greater the thermal stability. However, upon irradiation with a laser beam during writing, reading or erasing, especially when irradiating with a laser beam during writing, the amorphous alloy film becomes. 5 locally heated to about the Curie temperature at which the magnetization disappears. Therefore, in order to obtain a magneto-optical recording material that is resistant to thermal hysteresis by laser beam irradiation, it is necessary to take into account a Curie temperature Tc in addition to the crystallization temperature Tx. That is, the thermal stability relative to the thermal hysteresis can be improved by increasing Tx and at the same time maximizing the difference between Tx and Tc.

On the other hand, the Curie temperature is a criterion for the recording sensitivity. At a lower Curie temperature Tc in a temperature range where written information is stably retained (because the written information disappears due to a slight fluctuation in temperature at too low Tc, for example near room temperature), the power of a laser beam for writing becoming lower. That is, the recording sensitivity can be increased.

On the basis of these considerations, the inventors have the crystallization temperature Tx as a criterion for the thermal stability and the Curie temperature Tc as an important criterion for the recording sensitivity of amorphous films of the Fe-based alloy system Tb-Fe-Co having a high Kerr rotation angle 0 ^ provided, examined by adding various elements thereto.

In Figure 1, the changes in Tx, Tc and

Kerr rotation angle 0 per atom added additive element is shown when Fe of a characteristic Tb. , .Fec,, 31 ^ 6 ✓ / y 3 35 ^ amorphous film (surface ratio in the target) 5? Ó in the surface ratio is replaced by another element (B, Al, Ni, Nb, Ru, Rh, W, Ho or Er), where the positive values show an increase and the negative values show a decrease, and the star mark (*) represents the value 40 of the unreplaced amorphous Tb ^ 5 ^ 57 3 ^ 11 l -ft δ -5- . The higher Tx and the difference between Tx and Tc, the higher the thermal stability can be maintained. It is therefore necessary to choose an additive element that can increase Tx and replace Tc. / 5 layers, i.e. an additive element that has a greater difference. In that case, it is desirable to choose an additive element that can lower the value of the Kerr rotation angle ^ as an important property of the magneto-optical recording material. It is also desirable that the Curie temperature Tc be at least more than 100 ° C to be able to keep the written information in a stable manner.

As is apparent from the result shown in Figure 1, the present inventors have found that adding an additive element Nb, Ta, Rh, W,

Ho or Er is effective for a marked increase in the difference 4t - Atc with a small decrease in the Kerr Λ rotation angle, and also for a marked increase in thermal stability. It is also clear from Figure 1 that the addition of Al or Ni effective for corrosion resistance is not preferred due to thermal stability.

In order to obtain the said effect by adding the additive element Nb, Ta, Rh, W, Ho or Er, it is necessary that the content thereof is at least 0.5 atom%. In order to obtain the effect with a smaller decrease of the Kerr rotation angle, it is preferred that the content thereof is 0.5 to 10 atomic%.

Fig. 2 shows the dependence of the crystallization temperature and Kerr rotation angle in amorphous films of the composition ^ * 521 ^ e60 ^ ° 19 of a 0.3 Fe-based alloy system, in particular the degree of replacement when Fe is replaced by Nb, Ta, Rh, Er or Ho. It is clear from FIG. 2 that when the amount of the additive element added is greater than 10 atomic%, the perpendicular magnetic anisotropy is significantly reduced, and the Kerr rotation angle kk is decreased to less than 0.2. In order to obtain a sufficient reading as a material which can be used in practice, it is preferred that the amount of the added additive element is not greater than 10 atomic%. In order to significantly increase the corrosion resistance with a slight decrease in properties, it is more particularly preferred to add 3-8 atomic% of the additive element.

Of course, the same effect as above can be obtained by adding a total of 0.5-10 atomic% of two or more of the elements Nb, Ta, Rh, W, Ho and Er to optimize an improvement in the properties. Obviously, the present invention can be applied not only to amorphous rare earth transition metal films of the Fe-based alloy, but also to that of the Co-based alloy with a higher corrosion resistance than that of the Fe-based alloy . That is, in the case of the Co-based alloy, the writing is mainly performed using the magnetic compensation temperature Tcomp> and therefore the difference between Tx and Tc is not taken into account so much, but usually TcQmp is decreased to not more than 150 ° C, and thus the thermal stability can be improved by adding the additive element which can increase Tx, as in the present invention.

The effect of these additive elements Nb, Ta, Rh, W, Ho and W is also effective in the amorphous rare earth transition metal films of binary and quaternary alloy systems.

Examples of magneto-optical recording media of rare earth transition metal systems include Tb-Fe-Co, Tb-Fe, Tb-Gd-Fe, Tb-Sm-Fe, Gd-Dy-Fe, Gd-Sm-Fe, Tb-Co, Tb-Dy-Fe, Tb-Dy-Fe-Co, Tb-Gd-Fe-Co, Tb-Sm-Fe-Co, 30 Dy-Sm-Fe-Co, Gd-Dy-Fe-Co, Gd-Sm -Fe-Co, Gd-Ho-Fe-Co, Gd-Nd-Fe-Co, Gd-Pr-Fe-Co, etc.

Fig. 1 is a graph showing the changes of the crystallization temperature Tx, Curie temperature Tc and Kerr rotation angle as a function of the replacement of 1 atom% 35 when Fe of the Tb-Fe-Co amorphous film is replaced by an additive element R, Fig. 2 is a graph showing the changes of the crystallization temperature Tx and Kerr rotation angle 9 ^ when the added additive element changes to the amorphous 40 ^ 21 ^ 60 x ^ ° 19 ^ x (R = Nb, Ta, Rh, Er -7- * È or Ho), Fig. 3 is a graph showing changes in reflection R over time in the amorphous Tb-Fe-Co films. FIG. 4 is a graph showing changes of permeability T versus time in typical amorphous Tb-Fe-Co films.

The present invention will now be further described by way of an example.

In this example, the following amorphous alloy films are used. Tb-Fe alloy and Tb-Co alloy were used as the recording film of the binary system; Tb-Fe-Co alloy and Gd-Tb-Fe alloy as that of the ternary system; Tb-Dy-Fe-Co alloy of the Tb-Fe-Co 15 system, and Gd-Tb-Fe-Co alloy and Gd-Dy-Fe-Co alloy of the Gd-Fe-Co system as that of the quaternary system . Er, Ho, Nb, Ta, Rh, and W were used as additive elements. Al and Ni were used to compare these additive elements. An amorphous alloy film was formed on an 8 inch diameter Fe disk by magnetron sputtering using a composite target on which a 5 mm by 5 mm square plate of the rare earth element and a 10 mm by 10 mm square plate of the transition metal such as Co, etc. are provided in the surface area. The amorphous alloy film can be formed not only by sputtering, but also by vapor deposition, such as the multiple Co-evaporation by electron beam heating, etc.

Discs for writing and reading 30 were prepared by forming follow grooves on a 5 inch diameter glass disk with a UV resin, and successively depositing a Si film thereon (film thickness: about 1,000)), the amorphous alloy film (film thickness about 1,000)) and a SiO film (film thickness: about 1,000)).

As the substrate for the magneto-optical disc, polycarbonate (PC), acrylic resin (PMMA), epoxy resin, etc. can be used in addition to the glass used in the disc for determination. The 40 SiO film formed on the follow grooves improved the Kerr effect as an interference layer, -8- and can be formed by sputtering or vapor deposition. In addition to the SiO film, dielectric films of oxides such as ZrC ^ »^ a2®3 'etc *> nitrides such as Si ^ N ^,

Al, N, etc. are applied. The SiO film formed on the amorphous alloy 5 film had the effect of a protective layer to improve the life of the film and can be formed by sputtering, vapor deposition, etc. In addition to the SiO film, films of oxides, nitrides, polymeric materials, metallic materials, etc. with good weathering resistance are used.

The Kerr rotation angle θ ^, coercive force Hc, Curie temperature Tc and crystallization temperature Tx of typical amorphous alloy films used in this example are shown in the following table. Table 15 shows that the film properties are as follows:

Qk = 0.31 to 0.45 °

Hc = 2 to 10 KOe

Tc = 190 ° to 220 ° C

Tx = 400 ° to 415 ° C.

The writing and reading determinations of these recording films were performed at a constant write speed of 1200 rpm. The writing, reading, erasing was repeated with a write laser power of 8 mW, an external magnetic field Hex of 300 Oe, and a read laser power of 1.5 mW. As a result, it was found that the recording films containing Nb, Ta, Rh, W, Er or Ho showed no change in the C / N ratio on reading and showed high thermal stability even after more than 10 µl repeats. Discs with recording films other than above suffered a deterioration of the C / N ratio by a few dB after 10 µ repetitions.

The table does not show Tc for the Co-based alloys in the lower part because the writing was mainly performed using the compensation point, but the compensation temperature of these amorphous alloy films can be easily suppressed to no more than 150 ° C by optimizing their compositions. Therefore, Tx can be increased by adding Nb, etc., and therefore the thermal stability can be improved as described above.

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Table jT. : 5 ,,. J Hey (cool)! Tc (° C) I Tx <° C)!

Alloy fixture k (degrees) i_ï__ _: «Tb ^ -? E, nMb_; 0.22 | 4 I 140 [380 | * „Fes-.Cc.-Sb, 0.35 0.3 6; 200 410 j I, .3 3 <XO z _; _ j_ _1_; j Tb0 "Fe ~ -Cc." Ta- * '0-31 4! 200 y 405 y | 23 CC X, 3_1_I_I_l · _ j Tbn-Fe_Co, -Rh0 | 0.35 y 10 i 220 I 410

I 2d x3 3! ! * I

i 'j i! ! Tb-, Fe-, Co.0Ho. I 0.35! 5 y 210 j 400 (20 3o xS o *! I!

I ΐ i! I

Tb. 0Fe -, -> CoQSr. ! 0.33 {3 190 400

Tb. -Dv-Fe.-r-Co, -Sb-, j 0.35 2 190 | 450 13 7 co 1 / j {_ | _J_I_ -j-j-f —- y-

Gd -, "Tb," Fe'Tb- j 0.28 4 | 150 | 400 12 13 t 3 ^ __ i_i_ΐ_

GdlnTb.nFa..Co1nNb-! 0.41 | 3 y 200 j 410 xl xu o o 1U 3 ï t! --1y ---

Gd, „Tb, nFe„ „Co.n3h- i 0.45 3 f 190- I 400 12 10 o3 x0 3>! -1 - s-j -: -

Gd .-, Tb, „Fe„ -Co.nTa- ί 0.39 2 190 405 12 10 o3 xO 3 | ___

Gd, -Dv, “Fe-_Co-Nb-i 0.40! 2 200 415

Gd, -Dy, „Fe„ „Co.„ Ta- ί 0.40 j 2 210 410, 13 x'J bu XÜ 3 _j___

Gd. -Dv, -Fe..Co. , 3h -1 0.43 2 [200 400 y | 1 y! Tb- »Co ,, Nb- | 0.30 5 j 400 i A Ü / / J f__i_

Tb „„ Co- „Fe, -Nb., J 0.35 2 f - I 405 2G o2 1d 3! ! ----------------------- 1 '-'.....— 1 ....... t -? ...... .. — ....... I-

Tb. "Gd." CocoFe. "Nb, | C.38 2! - 410 10 10 62 ..o 3 1 __; _ j_ ^ 10 ^ 10i'O6oi: e17'a3 '0.35 | 3: “j 400 ^ 15 ^ 10 ^ 60 ^ 17 ^ 3 1 ° 39 j 2 | - | 405 -10-

Cases where the corrosion resistance has been taken into account in addition to the thermal stability will be described below.

Fig. 3 shows the changes of the reflection R with respect to time when characteristic amorphous films of Tb ^ gFe ^ gCo ^^, ^ 29 ^ 53 ^ 13 ^ 5 (R = A1, Nb, Ta, Rh, Er, W or Ho) was left at 60 ° C and a relative humidity of 95 van. The individual amorphous films were prepared in the same manner as above. The determination of the corrosion resistance, etc. was made in accordance with the change of the reflection with respect to time.

In Fig. 3 the normalized values with respect to the original reflection Rg are shown on the ordinate and curve 1 holds for ^ 2 ^ β ^ 0ο ^ jNb ^, curve 2 for T ^ c ^ e ^ C ^ -jAl ^, curve 3 for Tb2gFe ^^ Co ^^ Ta ^, curve 4 for Tb2gFe ^^ Co ^^ Rh ^, curve 5 for Tb2gFe ^ T-C0j :, curve 6 for Tbg ^ Fe · jgCo ^ j, curve 7 for Tbg ^ Fe ^ jCo ^ 3ΕΓ5 »curve 8 for Tb2gFe ^, and curve 9 for Tb2gFe ^^ Co.

It is clear from Figure 3 that when Co is added to the Tb-Fe film of curve 8, the change of the reflection factor R with time decreases as shown in curve 6, and when further Al, Nb, Ta , Rh or W is added to this Tb-Fe-Co 25 film, the change of the reflection factor R over time becomes much smaller, as shown by curves 1, 2, 3, 4 and 5, and therefore the corrosion resistance can be significantly improved. Al has poor thermal stability because it cannot increase crystallization temperature as much as can be seen from the result of Figure 1, while the addition of Nb, Ta, Rh or W can increase crystallization temperature and improve thermal stability . The films containing Nb, Ta, Rh or W, therefore, generally have excellent thermal stability and corrosion resistance.

Other additive elements such as Ho and Er can improve corrosion resistance, etc., by providing a protective layer that can seal it from the atmosphere, and thus can be used as a magneto-optical disc which is satisfactory in practice.

• \ .. «r- -11-

Fig. 4 shows the results of measuring the change of the film transmittance T relative to the aging time t when amorphous films of Tb__Fe ^ CoTO

- Zb OJ 1Δ »(curve 10), ^ 2 ^ 6, ^ 00 ^ 2 ^ 5 (curve 11), ^ 25 ^ 55 ^ 1jTa ^ 5 (curve 12), and Tb2 ^ Fe ^ yCo ^^ Nb ^ ( curve 13) were immersed in 1N NaCl. The permeability of the film increased significantly with an increased number of pores. As can be seen, therefore, the films of curves 11, 12 and 13, respectively.

Rh, Ta and Nb contain better protection against the appearance of pores, compared to the film of curve 10 which does not contain such an additive element, and therefore have a much better corrosion resistance.

-conclusions-

Claims (17)

Magneto-optical recording medium according to claim 1, characterized in that the additive element 10 is present in an amount not exceeding 10 atomic%. Magneto-optical recording medium according to claim 2, characterized in that the amorphous film is selected from Fe-based alloys containing 0.5-10 atom% 15 of at least one element selected from the group consisting of Er, Ho, Nb , Ta, Rh and W contain Co-based alloys containing 0.5-10 atomic% of at least one element selected from the group consisting of Er, Ta and W, and alloys whose transition metals are Fe ^ 5 * - ° q 5 20 and containing 0.5-10 atomic% of at least one element selected from Er, Ta and W. Magneto-optical recording medium according to claim 1, characterized in that the amorphous film is an Fe-based alloy. 5. Magneto-optical recording medium according to claim 2, characterized in that the amorphous film is an Fe-based alloy. Magneto-optical recording medium according to claim 1, characterized in that the amorphous film is an op 30 is Co-based alloy. Magneto-optical recording medium according to claim 2, characterized in that the amorphous film is a Co-based alloy. Magneto-optical recording medium according to claim 1, 35, characterized in that the amorphous film is a Tb-Fe-Co based alloy. Magneto-optical recording medium according to claim 2, characterized in that the amorphous film is a Tb-Fe-Co based alloy. 10. A magnetic-optical recording medium according to claim 1, characterized in that a protective layer is applied to the amorphous film. H. Magneto-optical recording medium according to claim 2, characterized in that a protective layer 5 is applied to the amorphous film. Magneto-optical recording medium according to claim 1, characterized in that an interference layer is arranged between the substrate and the amorphous film. Magneto-optical recording medium according to claim 2, 10, characterized in that an interference layer is arranged between the substrate and the amorphous film. Magneto-optical recording means, comprising a substrate and an amorphous film of a rare earth transition metal system, the amorphous film having at least 0.5 atom of at least one element selected from the group consisting of Nb, Ta, Rh and W as an additive element. Magneto-optical recording medium according to claim 14, characterized in that the additive element is present in an amount of not more than 10 atomic%. Magneti-optical recording medium according to claim 14, characterized in that the additive element is present in an amount of 3 to 8 atomic%. Magneto-optical recording medium according to claim 14, characterized in that the amorphous film is an op 25 is Fe-based alloy. Magneto-optical recording medium according to claim 15, characterized in that the amorphous film is an Fe-based alloy, Magneto-optical recording medium according to claim 14, 30, characterized in that the amorphous film is a Co-based alloy. Magneto-optical recording medium according to claim 15, characterized in that the amorphous film is a Co-based alloy. 21. The magnetic-optical recording medium according to claim 14, characterized in that the amorphous film is a Tb-Fe-Co-based alloy. Magneto-optical recording medium according to claim 15, characterized in that the amorphous film is a 40 Tb-Fe-Co based alloy. 14. The magnetic-optical recording medium according to claim 14, characterized in that a protective layer is applied to the amorphous film. 24.Magneto-optical recording medium according to claim 15, characterized in that a protective layer is applied to the amorphous film. Magneto-optical recording medium according to claim 14, characterized in that an interference layer is arranged between the substrate and the amorphous film. 26.Magneto-optical recording film according to claim 15, characterized in that an interference layer is arranged between the substrate and the amorphous film.