DE3150403A1 - Process for producing a recorded magnetic medium - Google Patents

Abstract

A mother medium (20), which is formed by a CoCr layer, and a daughter medium (17) having a TbFe magnetic layer (15), are brought into close contact with each other. Heat rays are radiated onto the daughter medium (17), so that the items of information in the mother medium (20) are transferred to the daughter medium (17). <IMAGE>

Description

"Process for the production of a recorded magnetic table

Medium The invention relates to a method for producing a recorded magnetic medium with the help of magneto-caloric transmission.

A recording medium that makes use of magneto-optical effects is used as a recording medium for recording with a high recording density has become known and is used for reproducing picture or sound information, such as e.g. provided as a video disk or PCM disk (PCM = pulse code modulation). The known Recording medium using magneto-optical effect is made of one magneto-optical (caloric) material, such as MnBi or CoP.

MnBi has a large magneto-optical effect and a vertical one magnetic anisotropy, so it can be magnetized perpendicular to its surface. In light of these properties, this material is suitable for high density recording the information has been investigated. Though continuous, intensive research have taken place, its use as a recording medium has been unsuccessful, because on the one hand the signal-to-noise ratio of the reproduced signal due to that occurring with the polycrystalline material Grain boundary noise is insufficient and, on the other hand, the material is chemically unstable. Recording media of the Co group have a preferred longitudinal direction of magnetization and are used for the longitudinal recording of information. In the area of a high recording density, in which condition 4 to wavelength of the recorded Signal / thickness of the magnetized layer is valid, is the area of demagnetization smaller than the demagnetization area in the direction perpendicular to the recording medium in the longitudinal direction so that the magnetic vector in the recording medium rotates and the magnetic transition point becomes indefinite, see NIKKEI ELECTRONICS, Aug. 7, 1978, pages 100-111. Data MR75-29, issued by Magnetic Recording Research Society of the Institute of F: l (ctronic Communication Fngineers of Japan, describes that, under suitable conditions, areas with sawtooth-shaped magnetic Domains occur and this prevents high recording density. Furthermore is one magnetic moment per magnetic in the region of a high recording density Unit area is very small due to the presence of demagnetization. As a result Significant problems arise in practical use when the material with the mentioned undesirable properties for recording and playback using a magneto-optical effect is used.

Fine compounds of rare earth metals and 3d transition metals, recently studied as a magnetic bubble material show one perpendicular magnetic anisotropy, a non-crystalline structure and a magneto-optical Effect. Properties of some examples of compounds of non-crystalline rare earth metals and 3d transition metals are listed in Table 1.

Table 1 Material Material 4t Ws (G) Hc (Oe) Curie tempera- recording direction tuition or com- compensation temperature th magnet temperature (° C) adjustable speed Gd-Co 3,500 10-100 Tcomp 120 Gd-Fe 0-400 10-100 Tc 230 1 Tb-Fe 0-400 lk-7k Tc 120 1 Dy-Fe 0-400 500 Tc 60 1 -2,000 The materials listed in Table 1 have the following advantageous properties: 1. Since they are non-crystalline, no K ("ng @ enze @ r is generated.

2. A high recording density is possible because of the perpendicular magnetic anisotropy when the materials have a sufficiently large coercive force Have hc.

3. Magneto-caloric recording with the help of a low-power laser is possible because the Curie temperature or the compensation temperature is 100 - 2000C is low.

Therefore, the materials listed in Table 1 are considered magneto-optical (caloric) recording materials are suitable. If those listed in Table 1 Materials for the production of magneto-optical (caloric) recording media in the To be used on a commercial scale, it is necessary to use the pre-recorded media to be produced in large numbers and at a low cost. The predominantly used for this Procedures use a contact transfer. In an example of the magnetic Transmission methods of this type are mother and daughter medium, which are on supply reels are wound in close contact with each other by a combination of a capstan shaft and applied pressure roller 1 C'n, passed through a magnetic coil 1 iii 1 ii r '(i #tj fWound up on reels Bias source is fed, mother and daughter medium by a magnetic Bias field generated by the solenoid is magnetized. During the The process of the hysteresis-free remanent magnetization causes a weak stray magnetic field, originating from the mother medium, the transmission of the recorded information from the mother medium to the daughter medium. This transfer is essential using the general magnetic recording method with a magnetic head similar to an alternating bias. This information transfer method is problematic, when targeting a medium with a high coercive force, such as CdCo, 1 '#> 1'N', Dy4 'urw. (see Table 1) is applied.

The invention is accordingly based on the object of providing a method for Manufacture of pre-recorded magnetic media to indicate through the information with a high recording density on recording media composed of a non-crystalline Compound rare earth metal-3d-transition metal with a high coercive force Hc can be recorded.

According to the invention, this object is achieved by the following process steps solved: - Use of a mother medium from cincr simple or complex CoCr layer that has a perpendicular magnetic anisotropy having - During the contact between mother medium and daughter medium the two media are brought to a predetermined temperature for transmission of the to the information recorded on the mother medium is heated to the daughter medium.

Advantageous embodiments of the invention are set out in the claims below specified. Advantages of the invention as well as of advantageous embodiments are can be found in the following description of an exemplary embodiment.

The invention is illustrated below with reference to one shown in the drawing Exemplary embodiment will be explained in more detail.

They show: FIG. 1 states of magnetization as a function of the Temperature Figure 2 shows a cross section through a mother medium and a daughter medium the implementation of the magneto-caloric transmission Ii 1 U 1 <'r 3 die sch < ~ ll # i. ~ # (~ d l I) .- # e schematic Dars t t '1 1 u i # <# des u 10ng des Inf rdes 1 i t> n t ~ 1 n #; -fers for a daughter medium that consists of a film with vertical Magnetization is formed, Figure 4 shows the information transfer when a film with perpendicular magnetization is used as the mother medium according to the invention becomes a magneto-caloric transmission method for the transmission of the data on the mother medium information recorded on the daughter medium is used. In this procedure becomes the daughter medium with a lower Curie temperature than that of the mother medium heated to develop a stray magnetic field. The daughter medium will magnetized by the stray magnetic field.

The principle of magneto-caloric transmission is discussed below are explained with reference to FIG. FIG. 1A illustrates the change as a diagram the remanent magnetization when the temperature changes from -T to Tc (Curie temperature) changes. In the area below Tc the magnetic moments are in the through Direction indicated by arrows aligned when the magnetic material is up to Saturation in this, Magnetized direction shown in Figure 1B is. When the temperature T is equal to or greater than the Curie temperature Tc, exceeds the energy of thermal movement the energy that directs the directions of the magnetic moments aligns so that the magnetic moments are randomly oriented, as shown in Figure 1C is shown. This results in zero magnetization, i.e. one unmagnelized Zusland. If among these Redingurlg there is an extremely magnetic The field acts on this magnetic material and the temperature of the magnetic Mat # ~ r j Is falls below Tc, the magnetic moments are in the magnetic Material aligned in the direction of the external magnetic field Hex like this is shown in Figure 1D. After applying the external magnetic field remains a remanent magnetization, which corresponds to the direction of the outer Magnetic field is aligned, even if the external magnetic field disappears. This means that the magnetic recording is carried out. The conditions for the mother medium for carrying out a magneto-caloric transmission are: 1. The Curie temperature rc of the mother medium is sufficiently higher than that of the daughter medium.

2. The medium must be a vertically magnetizable film in order to achieve a sufficient remanent magnetization even in areas with a high recording density to ensure.

3. The medium must be chemically stable.

A CoCr film has ideal properties for a mother medium, namely an ideal perpendicular magnetic anisotropy (d # h.

perpendicular to the surface), a high recording density, a good one chemical and thermal stability and a Curie temperature of 400 ° C or higher, as recorded in NIKKEW ELECTRONICS.

A method of performing magneto-caloric transmission using the CoCr film as the mother medium is described below.

In FIG. 2, a single CoCr layer 18 is used as the mother medium magnetic layer used, while in the daughter medium 17 a TbFe film 15 as magnetic layer is provided, wherein a SiO protective layer 16 with a thickness is deposited on the TbFe film 15 from several tens of nm to several hundreds of nm. To reduce the effect of the loss of space at the time of transmission, it is desirable that the protective film 16 be thin. The CoCr film 18 is on Substrate 19 formed by sputtering. To have a large remanent magnetization too the film 18 should be relatively thick, e.g. Even if the film is relatively thick, it has no impairment from demagnetization in the area of high recording density. This is an essential feature of the CoCr magnetization film with perpendicular magnetization. The TbFe film 15 is through Sputtering or vapor deposition is formed. It is preferably made as thin as possible, as long as it retains its perpendicular magnetic anisotropy to the sensitivity of the film during the broadcast. Al; w # jnsche1iswt'r t he! # ~ rich for the thickness of the film 15 there are a few tens of nm to a few hundred nrr. the magnetic layer 15 of the daughter medium 17 will be in close contact with the magnetic Layer 18 of the mother medium brought with the protective film 16 arranged between the two is.

Heating light rays 13 emitted by a bright source, such as for example a halogen lamp, are emitted on the mother medium directed from above the substrate 14 of the daughter medium 17. When the temperature of the magnetic layer 15 exceeds the Curie temperature Tc, the magnetic layer becomes 15 by the stray magnetic field of the magnetic layer 18 of the mother medium 20 accordingly the information stored on the mother medium 20 magnetized, so that a Information transfer takes place. To make a transfer with a To perform high recording density, the daughter medium 17 must pass through a film be formed with perpendicular magnetizability and - as mentioned above - one sufficient have large coercive force Hc.

In the case of using a film with longitudinal magnetizability, such as y Fe 2 O 3 with Co becomes in the area of high recording density with a recorded wavelength of about lu through the magnetic transition point d <#n Influence of the r) # 'm # Ignt t i 5 i e ru i0q u # idüf 1 ri 1 # r i c; difficult is to transfer the information to a daughter medium, as mentioned above. When a film having longitudinal magnetizability is used as the daughter medium 23 is, the daughter medium 23 is caused by the perpendicular magnetic field generated by the mother medium 26 is created, magnetized. As a result, the recording density is relatively low demagnetized regions are formed, as illustrated in Figure 3, whereby the signal-to-noise ratio is reduced.

In a mother medium 23 with a film with perpendicular magnetizability, are the directions of magnetization in the mother medium and in the daughter medium, into which the information is transmitted, in a 1: 1 ratio, as in Figure 1 shown. This avoids the problem described.

In this respect, too, it is therefore desirable to have a film with perpendicular magnetizability to be used as the mother medium.

A transparent material is used as the substrate for the daughter medium, such as glass or polymethyl methacrylate (PMMA) are used. The irradiation the thermal rays through the transparent material is used to heat the magnetic layer 15 at Tc or higher. Thereby the information in the mother medium to the daughter medium transfer. The mother medium can be a complex medium with a bilayer structure making a thin one Film of a material with a high permeability, such as Fe or FeNi, and a be formed thin CoCr film.

As explained in more detail above, for a high recording density suitable recording media are made by having a single CoCr layer with an excellent perpendicular anisotropy or a complex medium such as e.g.

CoCr-Fe and CoCr-FeNi can be used as the mother medium and the daughter medium by a non-crystalline rare earth 3d transition metal with a perpendicular magnetic anisotropy is formed.

Claims (8)

Claims: Method for producing a recorded magnetic Medium using a mother medium and a daughter medium from one non-crystalline rare earth 3d-transition metal material that is the mother medium brought into close contact with the daughter medium to transmit the information is not indicated by the following procedural steps: - Use a mother medium (20) recorded with information from a simple or complex one CoCr layer, which has a perpendicular magnetic anisotropy - during the Contact between mother medium (20) and daughter medium (17) will be the two media (17,20) to a predetermined temperature for transferring the data on the mother medium (20) recorded information is heated to the daughter medium (17). 2. The method according to claim 1, characterized in that for heating Heat rays are radiated onto the daughter medium (17). 3. The method according to claim 1 or 2, characterized in that the CoCr layer is made from CoCr # Fe or CoCr.FeNi. 4. The method according to any one of claims 1 to 3, characterized in that that the daughter medium (17) is constructed with a TbFe magnetic layer. 5. The method according to any one of claims 1 to 4, characterized in that that the mother medium (20) is constructed with a material which has a higher Curie temperature as the material of the daughter medium (17). 6. The method according to any one of claims 1 to 5, characterized in that that to form the daughter medium (17) a TbFe film (15) on a substrate (14) is applied and that a protective film (16) is formed on the TbFe film, the comes into close contact with the mother medium (20). 7. The method according to claim 6, characterized in that the TbFe film (15) is applied in a thickness of a few tens to a few hundred nm. 8. The method according to claim 6 or 7, characterized in that the The substrate (14) of the daughter medium (17) is formed from a transparent material will.