KR101423464B1 - Susceptor manufacturing apparatus - Google Patents

Abstract

The present invention relates to a susceptor manufacturing device by object transfer-influenced reaction and, more specifically, to a device capable of manufacturing a susceptor in which entire surface is concave by making a reactant react for the object transfer-influenced reaction and depositing the reactant on a base material to be inclined. The susceptor manufacturing device according to the present invention comprises: a vacuum chamber having a supply unit for supplying reaction gas and an outlet to discharge the reaction gas for a reaction; a control unit for controlling the temperature and pressure in the vacuum chamber and the supply amount of the reaction gas to causing deposition of the reaction in the vacuum chamber by the object transfer-influenced reaction; a jig installed in the chamber to support the base material; and a rotation member to rotate the jig.

Description

[0001] SUSCEPTOR MANUFACTURING APPARATUS [0002]

More particularly, the present invention relates to an apparatus for producing a susceptor by a substance-transfer-control reaction, and more particularly, to an apparatus for producing a susceptor by a substance transfer- To an apparatus capable of manufacturing a susceptor.

Carbon materials have attracted attention in high temperature applications because of their high strength and modulus, high heat shock resistance and light weight. Carbon materials are widely used as engineering materials and their applications include heaters, electrical contacts, high temperature heat exchangers, rocket nozzles, leading edges of airplane wings, as well as susceptors for manufacturing semiconductors and LED devices And the like. Of the various carbon materials, graphite is the most commonly used material for engineering materials.

However, the graphite material has low chemical resistance at high temperatures and can not be used in an oxygen or ammonia gas atmosphere. Therefore, it is very important to increase the chemical resistance of the graphite material so as to be widely used as a high-temperature material.

Therefore, a technique of forming a SiC and Si3N4 coating layer on a graphite material has been disclosed. The physicochemical properties of the graphite having the coating layer formed therein satisfy the requirements in various application fields and are regarded as the most effective method to overcome the drawbacks of the graphite material.

1 is a susceptor 100 for fabricating an LED in which a SiC thin film 120 is deposited on a substrate 110 made of a graphite material. Specifically, a sapphire wafer is used for the LED manufacturing process, and the sapphire wafer is supported by the susceptor 100 and manufactured through various processes. As shown in the figure, the SiC thin film 120 is coated on the base material 110 made of graphite for the above reason.

On the other hand, in the LED manufacturing susceptor 100, the surface (bottom surface) supporting the sapphire wafer is concave. This is because when the GaN thin film is deposited on the sapphire wafer, the sapphire wafer undergoes a process under a high-temperature atmosphere, since the sapphire wafer is deformed concavely downward. If the susceptor 100 supporting the sapphire wafer is formed flat without being concaved, the sapphire wafer is not entirely contacted with the concave sapphire wafer, thereby degrading the thermal uniformity of the sapphire wafer.

Therefore, the surface of the susceptor 100 supporting the sapphire wafer is concavely formed and brought into contact with the sapphire wafer over the entire surface, so that the thermal uniformity of the sapphire wafer can be maintained.

2 shows a manufacturing process of a susceptor 100 in which a surface is concavely formed. As shown, a surface 111 of a substrate 110 such as graphite is concavely formed, and then a SiC thin film 120 is coated on the substrate 110 by a chemical vapor deposition method.

On the other hand, as described above, graphite is often used as the substrate 110 of the susceptor 100 for fabricating LEDs. The graphite is processed into a concave shape with no concavity It is not easy to do.

Therefore, a new process for manufacturing the susceptor 100 having a concave surface is desperately required.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a method and apparatus for reacting a reactive substance to cause a mass transfer reaction, The present invention provides an apparatus capable of manufacturing a semiconductor device.

According to an aspect of the present invention, there is provided a susceptor manufacturing apparatus comprising: a vacuum chamber having a supply port through which a reactive gas is supplied and a discharge port through which a reaction gas is discharged; A control unit for controlling the temperature and pressure in the vacuum chamber and the supply amount of the reaction gas so that the reaction in the vacuum chamber is deposited by the mass transfer carrier reaction; A jig provided in the chamber to support the substrate; And rotating means for rotating the jig.

Preferably, the rotating means is a turntable on which the jig is mounted.

A susceptor according to the present invention includes: a substrate having a flat surface; And a coating layer concavely deposited on the substrate.

Further, it is preferable that the substrate is a graphite material, and the coating layer is a silicon carbide film.

Also, it is preferable that the coating layer is concavely deposited by reacting the reaction gas by a mass transferring reaction.

According to the present invention, there is an effect that a reactant can be reacted so that a mass transfer-dominating reaction takes place to produce a susceptor having a concave surface.

In other words, the reactive substance itself can be concavely deposited regardless of the surface morphology of the substrate on which the reactive substance is deposited.

Therefore, a substrate having a low processability is formed into a flat plate, and then the reactant itself is concavely deposited to produce a generally concave susceptor.

FIG. 1 shows a conventional susceptor for manufacturing an LED having a concave surface.
Fig. 2 shows a process of manufacturing the susceptor shown in Fig.
3 shows an apparatus for producing a susceptor according to the present invention.
4 shows a process for producing a susceptor according to the present invention and a produced susceptor.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The susceptor manufacturing apparatus 1 according to the present invention will be described with reference to Fig.

As shown in the drawings, the susceptor manufacturing apparatus 1 according to the present invention includes a vacuum chamber 10 in which a reaction proceeds. The vacuum chamber 10 is a conventional chamber in which a supply port 11 through which a reactive gas is supplied and an outlet 12 through which the reactive gas is discharged are formed.

A turntable (20) is provided in the vacuum chamber (10). The turntable 20 is a component rotated by a driving motor (not shown).

A jig 30 is mounted on an upper surface of the turntable 20 and a substrate 210 is mounted on an upper surface of the jig 30. [ Generally, the jig 30 may be composed of a mechanical chuck or an electrostatic chuck, and may be omitted. That is, the turntable 20 is a rotating means for rotating the base material 210.

The susceptor manufacturing apparatus 1 according to the present invention is provided with a control unit (not shown) for controlling process conditions of the vacuum chamber 10.

For reference, the reaction mechanism of supplying the reaction gas in the vacuum chamber 10 and depositing the substrate 210 on the substrate 210 can be largely divided into surface reaction control and mass transfer control reaction. The surface reaction dominance is a technique that is deposited at a low rate in a relatively low temperature atmosphere, and a mass transfer dominant reaction is a technique of depositing at a high rate in a relatively high temperature atmosphere.

Among them, the factor in the mass transfer control reaction is the amount of the reaction gas supplied. That is, in the mass transfer-dominating reaction, the deposition rate is determined by the amount of the reaction gas supplied, so that a reactant depletion effect occurs depending on the amount of the reaction gas supplied.

The control unit in this embodiment constitutes an atmosphere in the vacuum chamber so that the reaction in the vacuum chamber 10 responds to the mass transfer control reaction. More specifically, the interior of the vacuum chamber 10 is formed at 1,300 ° C to 1,800 ° C and 1 Torr to 300 Torr so that the reaction of the reaction gas becomes a mass transfer-dominated reaction. In particular, the amount of the reaction gas supplied into the vacuum chamber is controlled so that a depleting effect is generated in the reaction process. However, it is a matter of course that the temperature and the pressure vary depending on the kind of the deposition material and the structure and the form of the susceptor.

A method of manufacturing the susceptor according to the present invention will be described with reference to FIG.

First, a base material 210 made of graphite is loaded on the turntable 20. As shown in the drawing, the substrate 210 is flat (bottom surface) (see FIG. 4 (a)).

Next, before introducing the reaction gas, an atmosphere such as the internal temperature and pressure of the vacuum chamber is established so that the reaction in the vacuum chamber becomes the mass transfer-dominated reaction.

Next, a reactive gas is injected into the vacuum chamber, and a deposition material (SiC, 220a) is deposited on the substrate 210 by a chemical vapor deposition method. At this time, the deposition amount of the reaction gas is set so that the depletion effect is generated, so that the deposition material 220a is thinned (i.e., obliquely deposited) from one side of the substrate surface to the other side (see FIG. If the reactive gas is sufficiently injected, the depletion effect is not generated in the vacuum chamber, and the deposition material is deposited flat over the entire surface of the substrate.

Next, the base material 210 is rotated 180 degrees by using the turntable 20 (see (c) of FIG. 4).

Next, a reactive gas is injected into the vacuum chamber, and a deposition material (SiC, 220b) is deposited on the substrate 210 by a chemical vapor deposition method. At this time, the deposition amount of the reaction gas is adjusted so that the depletion effect is generated so that the deposition material 220b is inclined so as to be thinned from the other side of the surface of the substrate 210 (see FIG. 4 (d)).

The surface of the susceptor 200 thus formed is flat, but the coating layer 220 deposited on the substrate is concavely deposited, so that the surface of the susceptor 200 can be formed concavely as a whole will be. In other words, the susceptor 200 having a concave surface can be manufactured without forming the concave surface of the substrate 210.

In the present embodiment, the turntable rotates the substrate by 180 ° for convenience. However, the turntable rotates the substrate by 90 °, the deposition by the depletion effect, and the rotation of the substrate by 90 °. It is preferable to repeatedly deposit the deposition material concavely on the surface.

1: Manufacturing apparatus 10: Vacuum chamber
11: supply port 12: outlet
20: turntable 30: jig
200: susceptor 210: substrate
220: coating layer 220a, 220b: deposition material

Claims (1)

A vacuum chamber in which a reaction gas is supplied and a reaction chamber is formed through a discharge port;
A control unit for controlling a temperature and a pressure in the vacuum chamber so that the reaction in the vacuum chamber becomes a mass transferring dominating reaction;
A jig provided in the chamber to support the substrate; And
And rotation means for rotating the jig,
The control unit controls the injection amount of the reaction gas so that the reaction gas is depleted during the reaction,
Wherein the controller controls the injection amount of the reactive gas so as to cause a depleting effect during the reaction so that the deposition material is deposited in such a form that the deposition material becomes thinner from one side of the surface of the substrate to the other side.

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