JPH03247788A - Production of stamper for optical disk - Google Patents

Abstract

PURPOSE:To obtain a stamper for optical disk having superior shape precision of stamper grooves by subjecting an electroless Ni-P plating layer formed on a metallic substrate to mirror finish machining by the use of a single crystal diamond cutting tool and then applying grooving to the above layer by the use of a single crystal diamond cutting tool for grooving. CONSTITUTION:An electroless Ni-P plating layer (50mum thickness, 11.2% P content) 2 is formed on a metallic substrate 1. Subsequently, the surface of this layer 2 is finished into a mirror-like surface of <=0.002mumRa surface roughness by applying mirror finish machining to the surface of the layer 2 by the use of a single crystal diamond cutting tool 3 under the machining conditions of 5mum depth of cut and 10mum/rev feed rate. Further, as the cutting tool 3, a natural single crystal diamond is used. Then, grooving is applied to the layer 2 to form grooves 5 by using a single crystal diamond cutting tool 4 for grooving having an illustrated end shape, by which the desired stamper 6 for optical disk can be obtained. As a result, an optical disk substrate having superior working precision can be obtained, and further, the shortening of manufacturing time for renewing stamper is made possible.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a method for manufacturing a stamper for an optical disc, and more particularly to a stamper for molding an optical disc substrate.

(Prior Art) Conventionally, a stamper for an optical disk has been manufactured by the steps shown in the sixth section. That is, (a) after polishing the surface of the glass substrate A with high precision, (b) spin-coding photoresist 05) on the substrate side, (C) exposing the guide groove with a laser, and (d) developing. (e) make the surface of the original plate θω a conductor, (
f) Ni electroforming and collecting the electroformed material (hereinafter referred to as electroform transfer) to form master 07), (g) electroforming transfer of the master 0 to form mother 08), ( 11) The mother 0
8) was electroformed and transferred, and the standby angle θ was sampled. (i) Since the stand bar 02) is thin, having a thickness of about 0.3 mm, it is used as a stand bar (2) after a hard material 09) is bonded to the back side as a reinforcing material.

By pouring the resin into the above-mentioned standba Ql), heating it to the resin molding temperature, and collecting the resin after cooling, the standba C! 0
A resin optical disk substrate with the groove shape reversely transferred is manufactured. Note that if the stamper is used multiple times to manufacture the substrate and the shape accuracy of the groove deteriorates, the stamper is updated. After re-polishing the glass substrate, the renewal stamper performs the above (b)
) to (i).

(Problems to be Solved by the Invention) However, during the production of the optical disc substrate, the stamper is also heated to the resin molding temperature, so the bonding strength between the stamper and the hard material decreases, and the degree of adhesion decreases. As a result, there is a problem in that the shape accuracy of the resulting optical disc substrate deteriorates.

In addition, as mentioned above, many electroforming transfers are performed when manufacturing the stamper, and the shape accuracy of the grooves decreases with each transfer.
Another drawback is that the shape precision of the grooves of the stamper is not sufficient, and as a result, the shape precision of the grooves of the resulting optical disk substrate is low.

Therefore, solutions to the above problems were considered, and
Japanese Patent No. 3447 proposes a method using steps as shown in FIG. That is, (a) after polishing the glass substrate side, (1)) a thin film of Cr is deposited on the substrate 04, and a thin film of Au is deposited thereon.
(C) The two layers are cut with a diamond stylus (21) to form a guide groove to form an optical disk stamper (22).

However, similarly to the conventional method, when the stamper obtained by the method proposed above is used multiple times to manufacture an optical disk substrate, the accuracy of the groove shape deteriorates, so it is necessary to renew the stamper. The manufacture of the renewal stamper requires at least the re-polishing of the glass substrate, so there is a problem in that the manufacture takes a long time.

The present invention has been made in view of these circumstances, and its purpose is to obtain excellent shape accuracy of stamper grooves and processing accuracy of optical disk substrates, and to shorten the manufacturing time of replacement stampers. The present invention aims to provide a method for manufacturing a stamper for optical discs.

(Means for Solving the Problems) In order to achieve the above object, the method for manufacturing an optical disk stamper according to the present invention has the following configuration.

That is, in the manufacturing method according to claim 1, an electroless layer-P plating layer is formed on a metal substrate, the plating layer is mirror-cut with a single-crystal diamond cutting tool, and then a groove is cut with a single-crystal diamond cutting tool for grooving. This is a method of manufacturing a stamper for an optical disc, characterized in that a stamper for an optical disc is manufactured by forming a groove in the plating layer.

In the manufacturing method according to claim 2, after forming grooves in the plating layer in the manufacturing method according to claim 1, Ni electroforming is performed using the groove forming material as a grooved master plate for electroforming. This is a method for manufacturing a stamper for an optical disc, which is characterized in that a cast material is collected and made into a stamper for an optical disc.

(Function) As described above, in the method for manufacturing an optical disc stamper according to the present invention, an electroless Ni-P plating layer is formed on a metal substrate, so a plating layer with a relatively smooth surface is prepared. It is possible. Next, the plating layer is mirror-cut with a single-crystal diamond cutting tool, and since the cutting tool has excellent mirror-cutting and pressurizing properties, a metal substrate having a plating layer with an extremely smooth surface can be obtained. Note that the reason why the metal substrate is used is to form an electroless Ni--P plating layer.

After mirror cutting, grooving is performed using a single-crystal diamond tool for grooving.Since this hide has excellent grooving properties, it is possible to create grooves with excellent dimensional shape accuracy and sufficient depth by plating. It can be formed into layers. That is, unlike the conventional method in which guide grooves are exposed using a laser, there is no particular restriction on the thickness of the plating layer, and grooves of the desired size and shape can be formed in a sufficiently thick plating layer. will be obtained. Therefore, it can be used as a stamper as it is without bonding a reinforcing material (hard material), and therefore the processing accuracy of the optical disk substrate is improved.

Furthermore, since the above manufacturing method does not involve a transfer step such as electroforming transfer, the shape accuracy of the grooves does not deteriorate due to transfer, and therefore a stamper having excellent groove shape accuracy can be obtained.

Furthermore, since the stamper can be made with a thick plating layer as described above, there is no need for re-plating when manufacturing a renewal stamper, and it is sufficient to start with mirror cutting of the plating layer and then grooving. Therefore, the number of processing steps is small,
The manufacturing time of the renewal stamper can be shortened.

Further, since the above manufacturing method requires only one electroforming transfer, which is small, a stamper with excellent groove shape accuracy can be obtained.

Furthermore, since the renewal stamper can be manufactured by starting with mirror cutting of the plating layer of the groove forming material, the manufacturing time can be shortened and completed.

Note that when an optical disk substrate is manufactured using the stamper obtained by the manufacturing method according to claim 1, the convex portions of the grooves of the stamper (grooves formed by grooving) become four parts of the substrate and are reversely transferred. During the grooving process, it is necessary to form the stamper protrusions corresponding to the required shapes of the four parts of the substrate.

On the other hand, in the case of the stamper obtained by the manufacturing method according to claim 2, the recesses of the grooves of the groove forming material (grooved material) correspond to the recesses of the optical disc substrate.
In the grooving process, the groove-shaped bottom material recess may be formed in accordance with the desired shape of the substrate recess.

Therefore, it is only necessary to select and use one of the above methods depending on the required shape of the substrate recess, and in cases where the substrate recess is deep and sandwiched between the substrate, it is possible to In such a case, the manufacturing method according to claim 2 is more suitable.

(Example) FIG. 1 shows a schematic diagram of the manufacturing process of an optical disc stamper according to Example 2.

As shown in FIG. 1, (a) first, electroless Ni-P plating layer (2) (thickness 50 μm, P amount: 1
(b) Next, a plating layer (2) is formed.
In order to improve the surface shape accuracy, use a single crystal diamond cutting tool (3) (tip radius: 20R), depth of cut: 5μ.
m, feed: 101t m/rev cutting conditions,
The surface of the plating layer (2) is mirror-cut to obtain surface roughness:
Finished with a mirror finish of 0.002 μm Ra or less. Incidentally, a natural single crystal diamond was used for the above single crystal diamond high l-(3'l).

(C) Next, using a single-crystal diamond bit for grooving (4) having the tip shape shown in Fig. 3, the plating layer (2) is
Grooving was performed to form grooves (5). During this machining, in order to keep the groove depth constant, a micro-cutting tool stand (9) shown in Figs. The voltage applied to the piezoelectric element (11) was controlled so that the groove depth was constant.

Groove (5) has a groove depth of 0.017 zm and a groove pinch 21.
It was made into a spiral shape by turning to a thickness of 6 μm.

The groove forming material obtained in the above step (C) had extremely superior groove shape accuracy compared to the stamper obtained by the conventional method.

The groove forming material is used as a stamper (6), and the stamper (6) is
) An optical disk substrate (7) made of polycarbonate resin was manufactured, on which the groove shape of the groove was reversely transferred. The processing accuracy of the substrate (force) was extremely superior to that obtained using a stamper obtained by a conventional method.

The production of optical disk substrates using the stamper (6) was repeated, and when the accuracy of the groove shape decreased, a replacement stamper was produced. The production involves mirror-cutting the plating layer (2) of the stamper (6) in the same manner as in step (b),
Grooving was performed in the same manner as in step (C) above. The time required for this manufacturing was extremely short compared to that for manufacturing a renewal stamper using the conventional method.

Actual difference fl A schematic diagram of the manufacturing process of the optical disk stamper according to the second embodiment is shown in FIG. 2.

As shown in FIG. 2, first, a groove forming material having the same groove shape as in Example 1 was manufactured through the same steps (a), (b), and (C). (d) Next, the groove forming material was used as a grooved master disk for electroforming (8), Ni electroforming was performed, and the electroforming material was collected to form an optical disc stamper 02).

The stamper 02) had extremely superior groove shape accuracy compared to stampers made by the conventional method.

Using the stamper 02), a hard material 09) was bonded together to produce an optical disc substrate 03) made of polycarbonate resin. The processing accuracy of the substrate was extremely superior to that obtained using a stamper obtained by a conventional method.

The production of optical disk substrates using the above-mentioned stamper 02) was repeated, and when the shape precision of the grooves decreased, a replacement stamper was produced. This production was performed by mirror-cutting, grooving, and Ni electroforming the plating layer (2) of the electroforming master (8) in the same manner as in steps (b) to (d).

The time required for this manufacturing was extremely short compared to that for manufacturing a renewal stamper using the conventional method.

In the case of Example 1, the four parts of the groove of the groove forming material correspond to the recessed parts of the optical disc substrate, and in the case of Example 2, the four parts of the groove of the groove forming material correspond to the four parts of the optical disc substrate.

(Effects of the Invention) According to the method of manufacturing a stamper for an optical disk according to the present invention, a decrease in groove shape accuracy due to transfer does not occur, so that a stamper having excellent groove shape accuracy can be obtained.

Furthermore, since a stamper with a large thickness can be obtained, it can be used as a stamper as it is without bonding a reinforcing material to it, thereby improving the processing accuracy of the optical disk substrate. Furthermore, when manufacturing the renewal stamper, the number of manufacturing steps is reduced, and the time required for manufacturing can be significantly shortened.

[Brief explanation of drawings]

The first part is a schematic diagram of the manufacturing process of the stamper for optical discs according to Example 1, FIG. 2 is a schematic diagram of the manufacturing process of the stamper for optical discs according to Example 2, and FIG. Figure 4 shows the shape of the tip of a diamond bite.
FIG. 5 is a front view of the micro-cutting tool stand for grooving, FIG. 6 is a diagram showing the manufacturing process of a conventional stamper for optical disks, and FIG. 7 is a special It is a figure which shows the manufacturing process of the standber for optical discs described in the patent publication 62-3447. (1) - Metal substrate (2) - Electroless Ni-P plating layer (3) - Single crystal diamond height (4) - Single crystal diamond bite for grooving (5) - Groove (6) 02) C! 1 (22) - Stamper for optical disc (7) - Optical disc substrate (8) - Master disc for electroforming (9) - Fine cutting tool stand 00) - Non-contact displacement meter 01
)-Piezoelectric element (+3L-Optical disk board 04
) - Glass substrate θω - Photoresist 0ω - Grooved glass original plate 07) - Master θB) - Mother
09)-Hard material (21L-Diamond stylus

Claims (2)

[Claims] (1) Form an electroless Ni-P plating layer on a metal substrate, mirror-cut the plating layer with a single-crystal diamond cutting tool, and then grooving with a single-crystal diamond cutting tool to make grooves in the plating layer. 1. A method for producing a stamper for an optical disc, the method comprising: forming a stamper for an optical disc. (2) Form an electroless Ni-P plating layer on a metal substrate, mirror-cut the plating layer with a single-crystal diamond cutting tool, and then grooving with a single-crystal diamond cutting tool to make grooves in the plating layer. A method for producing a stamper for an optical disc, comprising: forming a grooved master for electroforming, performing Ni electroforming using the master, and collecting the electroformed material to form a stamper for an optical disc.