NL8500085A - MAGNETIC REGISTRATION MEDIUM. - Google Patents

Description

B Br / SE / Sony-1671 t "Magnetic recording medium".

-1-

The invention relates to a magnetic recording medium with a thin film of ferromagnetic metal formed by vacuum evaporation.

Such recording media, in which the ferrous

O

Magnetic film which may have a thickness of several hundred A units up to about one micron are usually obtained by electrolytic or non-electrolytic coating, by ion bombardment, by sputtering or by vacuum evaporation on a non-magnetic substrate, and may then provide high-density registrations. The method of vacuum evaporation at an oblique angle (U.S. Pat. No. 3,342,632) has proved particularly important because it provides a magnetic recording medium of high coercive force.

The vapor flow of the metal to be deposited on a substrate is directed at an oblique angle towards the substrate. However, with a magnetic recording medium with a thin film of ferromagnetic material, the video signal supplied at short wavelengths is not always strong enough, while the noise is often too great. Therefore, no magnetic recording medium has yet been obtained which provides a sufficiently large signal-to-noise ratio.

The object of the invention is to provide a magnetic recording medium of the type mentioned, which has an improved signal-to-noise ratio.

It provides a magnetic recording medium, 8500085 4 '- »-2 - comprising a non-magnetic substrate with a layer of ferromagnetic metal formed thereon by physical evaporation in vacuum, characterized in that the ferromagnetic metal layer consists of columnar crystals which have an inclined position relative to the substrate and wherein each columnar crystal contains ferromagnetic metal particles and oxide particles of the ferromagnetic metal, which are randomly distributed over the columnar crystals.

Since in this recording medium the oxide particles of the ferromagnetic metal are randomly distributed over the columnar crystals of the thin ferromagnetic film, the fine crystals of ferromagnetic metal in these columnar crystals are, as it were, fractionated. This lowers the noise in terms of the electromagnetic conversion properties, so that a thin film type magnetic recording medium having a large signal to noise ratio is obtained.

In other words, the magnetic recording layer consists of an aggregate of columnar crystals, while each of the columnar crystals has a random distribution of ferromagnetic metal particles and oxide particles of ferromagnetic metal.

The recording medium according to the invention has a low noise and a large signal-to-noise ratio.

The reason why the noise is reduced by the random distribution of the oxide particles as vapor-deposited material in the column crystals is probably that the grain sizes of the vapor-deposited magnetic metal particles in the same crystals remain small as a result.

The invention will be further described by means of the following examples and the drawings.

Figure 1 shows a schematic view of a vacuum evaporation apparatus which can be used in the invention. This device 1 has a vacuum chamber 2 8500085 * -3- in which a vacuum atmosphere with a predetermined amount of oxygen can be maintained. In the vacuum chamber 2 there is a metal drum 3 and also a non-magnetic substrate 4 which goes from a supply reel 5 via the drum 3 to a take-up reel 6. A source 7 for the magnetic metal to be vapor-deposited, such as Co, Ni or an alloy thereof, is arranged some distance below and opposite the drum 3. Between the drum 3 and the evaporation source 7 there is a shielding plate 8, which ensures that the metal evaporated from the source 7 is deposited on the non-magnetic substrate 4 only at a predetermined oblique angle. In the case of a Co-Ni alloy, the nickel content is preferably no more than 30 atomic%.

15

Example I

Using said device, a cobalt-nickel alloy (80 atom% Co220 atom% Ni) was deposited at an oblique angle on a non-magnetic substrate 4 of polyethylene terephthalate. The substrate had a thickness of 10 µm, while the pressure in the vacuum chamber was 1 x 10 Torr, obtained by introducing oxygen gas with a. speed of 100 cc / min. The vapor-deposited metal hit the substrate at an angle of 40-90 °, while the source 7 was heated with an electron beam. In this way, a magnetic tape was made with a vapor-deposited cobalt-O "> nickel film of 1000 A thickness. The magnetic properties were as follows: j,» 30 Coercive force (Hc): 820 Oe f

Saturated Flux Density (Bm): 6800 G Residual Flux Density (Br): 4900 C

Rectangularity ratio (Br / Bm): 0.72. \

The magnetic tape thus obtained was transversely

35 cross section observed with the aid of a transmission electrical M

8500085 Ü & -4-thrones microscope. The clear image thus obtained showed that the deposited magnetic layer consisted of an aggregate of fine columnar crystals and that all columnar crystals were at an angle of 60 to 65 ° with the substrate. The width of the columnar crystals

O

was 50-100 A. On the other hand, the dark image obtained with this microscope showed that cobalt-nickel

O

little ones with dimensions from 50 to 100 A and cobalt nickel

O

oxide particles with dimensions of 30 - 70 Å were evenly distributed over each of the columnar crystals.

Fig. 2 schematically shows a columnar crystal from the magnetic layer of the magnetic tape of Example I. Reference numeral 10 denotes the crystal with

O

a width of 50 to 100 A. Furthermore, one sees the cobalt

O

15 nickel particles 11 with dimensions of 50 - 100 A and the

O

cobalt-nickel oxide particles with dimensions from 30 to 70 A.

Comparative example 1

Under the same conditions as in Example I

a magnetic tape was made with the proviso that no oxygen gas was introduced into the vacuum chamber, so that the pressure was -5 1 x 10 Torr and the hit angle of the vapor-deposited metal particles on the substrate was 70 to 90 0. The deposited cobalt-nickel film had a thickness

O

1000 A and the magnetic properties of the magnetic tape were as follows:

Coercive force (Hc): 800 Oe Saturated flux density (Bm): 6900 G 30 Residual flux density (Br): 6280 G

Rectangularity ratio (Br / Bm): 0.91.

Observation of the magnetic layer with a transmission electron microscope in the same manner as in Example 1 showed that an uneven distribution of metal particles and metal oxide particles had arisen.

8500085 -5-

Example 11

A magnetic tape was made in the same manner as in Example I, except that cobalt (100%) 5 was now used as the magnetic material. The deposed

O

cobalt film had a thickness of 1000 Å and the magnetic properties were as follows:

Coercive Force (Hc): 910 Oe Saturated Flux Density (Bin): 7300 G

10. Residual flux density (Br): 5300 G

Rectangularity Ratio (Br / Bm): 0.73 Observation of the cross-sectional magnet layer showed columnar crystals of the same construction as in Figure 2, i.e. with a random distribution of cobalt particles and cobalt oxide particles. The cobalt particles had

O

dimensions of 50-100 Å and the cobalt oxide particles

O

dimensions from 30 - 70 A, while the columnar crystals

O

had a width of 50-100 A.

20 Comparative example 2

A magnetic tape was made in the same manner as in Example II, except that no oxygen gas was introduced into the vacuum chamber, so that the pressure there was 1 x 10 5 Torr, and the hit angle of the vapor-deposited particles on the substrate was 70 to 90 0. The vapor-deposited O "layer had a thickness of 1000 Å and the magnetic properties were as follows:

Coercive Force (Hc): 900 Oe "j

30 Saturated Flux Density (Bm): 7500 G

Residual flux density (Br): 6800 G Rectangular ratio (Br / Bm): 0.91 When observed with a transmission electron microscope, there was no uniform distribution between cobalt; 35 particles and cobalt oxide particles exist. j f 8500085 j.

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The following table summarizes the results of electromagnetic imaging tests with the magnetic tapes from the above examples. The signal level and the noise level were measured with a spectrum analyzer using a ferrite magnetic head with a slit length of 0.2 microns and a relative tape speed of 3.8 m per second. The table shows relative values for the output signal (at a signal of 5 MHz) and for the signal-to-noise ratio, the 10 values for the magnetic tape of comparative example 1 always being set at 0 dB.

Table 15 Output signal Signal-to-noise ratio (5 MHz)

Example I -1.5 dB + 2.0 dB

Example II -0.8 dB + 3.9 dB

Comparative example 1 0 dB 0 dB

Comparative example 2 +1/4 dB +0.4 dB

When comparing Example I with Comparative Example 1 (both with a magnetic layer of cobalt-nickel), the coercive force Hc appears to be almost the same in both cases, while the values for Br and for Br / Bm in the comparative Example 1 are larger. .

Furthermore, it appears from the table that the signal output at the band of Example 1 is weaker than at the band of Comparative Example 1, while the signal-to-noise ratio is still much larger, which indicates a greatly reduced noise.

Observation with a transmission electron micro-coop showed that the cobalt-nickel fine crystals and cobalt nickel 8500085 ^ ...... "" "UIHIIIÏ ........" iiwriei ^^ i -7- " nickel oxide are randomly distributed over the columnar crystals of the magnetic layer, as shown in Figure 2. Conversely, the columnar crystals of the magnetic layer of Comparative Example 1 consisted only of fine cobalt nickel crystals.

In Example I, the fine cobalt nickel crystals of the columnar crystal were fractionated and formed into small particles. In contrast, the fine cobalt nickel crystals in Comparative Example 1 were not fractionated by oxide-10 particles. Since the fine cobalt-nickel crystals in Example I are smaller in size than those in Comparative Example 1, the electromagnetic conversion noise is clearly reduced.

If Example 2 is compared with Comparative Example 2 (both with a magnetic layer of cobalt), the coercive force Hc is virtually the same in both cases, while the values for Br and for Br / Bm in comparative Example 2 are larger. It can be seen from the table that although the output signal in Example II is weaker than in Comparative Example 2, the signal-to-noise ratio is much better, resulting in reduced noise.

Observation with a transmission electron microscope showed that the fine crystals of cobalt and cobalt oxide are randomly distributed in the columnar crystals of the magnetic layer of Example II. In contrast, the columnar crystals of the magnetic layer of Comparative Example 2 consisted only of fine cobalt crystals. In Example II, the fine cobalt crystals were fractionated and formed into fine particles. However, in Comparative Example 2, the fine cobalt crystals were not fractionated by oxide particles. Since the particle size of the fine cobalt crystals in Example 2 is therefore smaller than in Comparative Example 2, lower noise is found in electromagnetic conversion. j:>! t; 8500085 Ü f t -8- • η

As the ferromagnetic metal, cobalt, nickel or an alloy thereof can be used.

8500085

Claims (8)

Magnetic recording medium, comprising a non-magnetic substrate with a layer of ferromagnetic metal formed thereon by physical evaporation in vacuum, characterized in that the ferromagnetic metal layer consists of columnar crystals which have an inclined position relative to the substrate and each columnar crystal contains ferromagnetic metal particles and oxide particles of the ferromagnetic metal, which are randomly distributed over the columnar crystals. Recording medium according to claim 1, characterized in that the ferromagnetic metal is cobalt. Recording medium according to claim 1, characterized in that the ferromagnetic metal is a cobalt-nickel alloy with no more than 30 atomic% nickel. Recording medium according to claim 1, characterized in that the ferromagnetic metal layer is formed by vacuum evaporation with an oxygen-containing atmosphere. Recording medium according to claim 1, characterized in that the ferromagnetic metal layer has a thickness O between 300 and 10000A. 6. Recording medium according to claim 1, characterized in that the columnar crystals have a width O i between 50 and 100 A. Recording medium according to claim 1, characterized in that the ferromagnetic metal particles have an O grain size between 50 and 100 A. 30 Recording medium according to claim 1, characterized in that the oxide particles have a grain size between O 30 and 70 A. 8500085