KR20170006841A - Apparatus for mocvd - Google Patents

Abstract

The present invention relates to a metal organic chemical vapor deposition device which includes a substrate accommodating chamber, a susceptor, and a heater. A plurality of substrates placed on the susceptor is heated with inert gas supplied through a gas flow path while being revolved and rotated by a gas injection table so that the substrates can be heated at a uniform temperature and the uniformity of the thin film can be improved by the stable flow of a reaction gas. In addition, when replacing the susceptor for maintenance, for example, replacing the susceptor in the chamber due to contamination, a main disk, the gas injection table, and a sub disk can be easily separated from a susceptor bottom disk and a susceptor shaft so that only required components can be easily replaced and the maintenance cost can be reduced.

Description

[0001] APPARATUS FOR MOCVD [0002]

The present invention relates to an organometallic chemical vapor deposition apparatus, and more particularly, to an apparatus for depositing an organometallic chemical vapor deposition apparatus, in which a plurality of substrates placed on a susceptor are heated while being rotated to heat the substrate to a uniform temperature, And more particularly, to an organometallic chemical vapor deposition apparatus capable of improving the chemical vapor deposition apparatus.

As high efficiency light emitting diodes (LEDs) are increasingly used in various industrial fields, there is a demand for equipment capable of mass production without deteriorating quality or performance. Organometallic deposition reactors are widely used for the production of such light emitting diodes.

The metal organic chemical vapor deposition (MOCVD) apparatus supplies a mixed gas of a Group 3 alkyl (organic metal source gas) and a Group 5 reaction gas and a high purity carrier gas to a reaction chamber, Thereby growing compound semiconductor crystals. In such an organometallic chemical vapor deposition apparatus, a substrate is mounted on a susceptor and a gas is injected from above to grow a semiconductor crystal on the substrate.

As a conventional organic metal vapor deposition apparatus, an organometallic chemical vapor deposition apparatus as disclosed in Korean Patent Laid-Open No. 2001-0009504 has been proposed. In a conventional metalorganic chemical vapor deposition apparatus, a chamber body, a chemical transfer module, a vacuum system, and a showerhead assembly are provided so that the reaction gas is supplied to the reaction space in the chamber through the showerhead assembly, A thin film is deposited on a substrate by a remote plasma in space.

However, in the above-described conventional MOCVD apparatus, a plurality of substrates are rotated about the axis of the susceptor and heated by the lower susceptor to deposit a thin film on the substrate. However, So that the thin film can not be uniformly deposited.

In addition, in the above-described conventional MOCVD apparatus, the reaction gas supplied into the chamber is attached to the inner surface of the chamber and the susceptor, so that the inside of the chamber and the susceptor are liable to be contaminated. In addition, in the conventional metalorganic chemical vapor deposition apparatus, the reaction gas is supplied from the upper showerhead assembly. In this case, in an organic metal chemical vapor deposition process using a material which is a fine particle itself and a reaction which is easy to generate particles as a metal organic compound, the nozzle of the showerhead is clogged, and thus, on a plurality of substrates mounted on the susceptor The uniformity of the deposited thin film is disadvantageously deteriorated.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-described problems of the prior art, and it is an object of the present invention to provide a method and apparatus for heating a substrate while rotating a plurality of substrates placed on a susceptor, The present invention provides an organometallic chemical vapor deposition apparatus capable of improving uniformity of an organic metal vapor deposition apparatus.

Another object of the present invention is to provide an organometallic chemical vapor deposition apparatus capable of easily separating and replacing and maintaining only a necessary structure when replacing a susceptor in order to maintain the susceptor, .

According to an aspect of the present invention, there is provided an apparatus for depositing metal organic chemical vapor according to the present invention, comprising: a substrate accommodating chamber including a chamber lid, an outer wall, and a bottom flange; And a heater for heating the substrate mounted on the susceptor, wherein the susceptor is mounted on the substrate, the susceptor being mounted on the susceptor, A main disk having a plurality of receiving pockets for receiving the sub-disc and communicating with the gas channels, and a susceptor shaft having a vertical gas channel formed therein for rotating the main disc and communicating with the gas channels, .

The susceptor may include a gas injection table disposed between the main disk and the sub disk and having a gas supply hole communicating with the accommodating pocket.

Here, the gas supply hole of the gas injection table may include a floating gas supply hole formed vertically in the thickness direction of the gas injection table to float the sub-disk by a supplied gas, And a rotating gas supply hole for rotating the sub disc by a supplied gas formed obliquely with respect to the sub-disc.

Here, the floating gas supply hole and the rotation gas supply hole are integrally formed.

The susceptor includes a susceptor bottom disk fixed to the susceptor shaft, and the main disk is detachably coupled to the susceptor bottom disk.

Here, the upper surface of the gas injection table is formed with a lower step toward the outer circumferential surface, and a step corresponding to the step of the gas injection table is formed on the lower surface of the sub disk.

Here, the rotary driving gas is an inert gas.

According to the present invention having the above-described configuration, a plurality of substrates placed on a susceptor are heated while rotating and revolving the plurality of substrates with an inert gas supplied through the gas flow path and the gas injection table, And the uniformity of the thin film can be improved by the stable flow of the reaction gas at the same time of heating.

When the susceptor in the chamber is contaminated and replaced for maintenance of the susceptor, the main disk, the gas injection table, and the sub disk are easily separated from the susceptor bottom disk and the susceptor shaft Therefore, only necessary configuration can be easily changed, and the maintenance management cost can be reduced.

1 is a view showing an organometallic chemical vapor deposition apparatus according to the prior art.
2 is a cross-sectional view illustrating an apparatus for depositing an organometallic chemical vapor according to the present invention.
3 is an enlarged view of a portion A in Fig.
4 is a view showing a sub disk and a gas injection table of the present invention.
5A and 5B are views showing various examples of the gas flow path of the present invention.
6A is a perspective view of the gas injection system of the present invention, FIG. 6A is a perspective view thereof, FIG. 6B is a plan view, FIG. 6C is a cross-sectional view taken along line B-B ' to be.
7A and 7B are views showing various examples of gas supply holes of the gas injection table of the present invention.
8 is a view showing another embodiment of the gas injection table and the sub disk according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an apparatus for depositing an organometallic chemical vapor deposition apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a view showing an apparatus 1 for depositing an organometallic chemical vapor according to the present invention.

2, the organometallic chemical vapor deposition apparatus 1 according to the present invention includes a substrate accommodating chamber 10, a heater 20, a susceptor 30, a sealing portion 40, a gas And a supply unit 50.

The substrate accommodating chamber 10 includes a chamber lid 11 covering an upper portion of the chamber, an outer wall portion 13 coupled to the chamber lid 11 and covering a side portion of the chamber, And a flange portion (12).

The chamber lid 11 is detachably connected to the outer wall 13 through a sealing and fastening means such as a double O-ring seal 11a and a clamp and the chamber lid 11 is cooled And a lead cooling flange 11b can be formed on the chamber lid 11. [ The cooling passage 11a is configured to allow a cooling medium such as cooling water or a cooling gas to flow so as to cool the substrate accommodating chamber 10 heated by the high temperature heat generated in the deposition process in the substrate accommodating chamber 10 .

The outer wall portion 13 is fastened to the chamber lid 11 and is configured to cover the side of the substrate accommodating chamber 10.

A bottom flange portion 12 is provided under the substrate accommodating chamber. A cooling passage 12b is formed in the bottom flange portion 12 and a bottom cooling flange 12a is formed in the bottom portion of the bottom flange portion 12. [ The cooling passage 12b is configured to allow a cooling medium such as cooling water or a cooling gas to flow so as to cool the substrate accommodating chamber 10 heated by the high temperature heat generated in the deposition process in the substrate accommodating chamber 10. [ .

Inside the substrate accommodating chamber 10, a heater 20 for heating the substrate is provided.

The heater 20 is formed of, for example, an induction coil 21, and is configured to heat the substrate W disposed on the heater.

An exhaust part 60 is formed on the outer side of the heater 20 inside the outer wall part 13 and the exhaust part 60 is connected to a gas exhaust line (not shown) And to discharge the reaction gas remaining in the substrate accommodating chamber 10 to the outside of the substrate accommodating chamber 10 through the exhaust portion 60 and the gas exhaust line.

A sealing portion 40 is provided between the bottom flange portion 12 of the substrate accommodating chamber 10 and the susceptor shaft 41 so that the susceptor shaft 41 and the bottom flange portion 12, As shown in Fig. The sealing part 40 is filled with a fluid seal. In this embodiment, the fluid seal may be formed of a magnetic fluid seal sealing the air gap with the outside by a magnetic force of magnetism.

Meanwhile, a gas supply unit 50 is installed at the center of the substrate accommodating chamber. The gas supply unit 50 is configured such that the reactive gas is radially spread from the center of the substrate accommodation chamber through the central gas injector as shown in Fig.

In the substrate accommodating chamber, a susceptor 30 on which the substrate W is mounted is disposed below the gas supply unit 50.

In the present invention, the susceptor 30 is configured to rotate the plurality of substrates by a rotary driving gas in which a plurality of substrates are mounted and a gas flow path is formed and supplied through the gas flow path.

2 to 8, the susceptor 30 includes a main disk 31, a gas injection table 32, a sub disk 33, a susceptor bottom disk 34, And includes a shaft 41.

One end of the susceptor shaft 41 is connected to the susceptor bottom disk 34 of the susceptor 30 and the other end thereof penetrates the bottom flange portion 12 of the substrate accommodating chamber 10, (Not shown) disposed outside the substrate accommodating chamber 10 to rotate while supporting the susceptor 30.

The susceptor shaft 41 may further include a thermal barrier 42 inside the susceptor shaft 41. The thermal barrier 42 can prevent the high temperature heat of the induction coil 21 of the heater 20 from being transmitted to the gas supply unit 50. In the present embodiment, the susceptor shaft 41 and the thermal barrier 42 may be formed of quartz or boron nitride (BN) material having high durability against high temperatures, for example.

A vertical gas flow path 44 and a gas introduction path 43 are formed in the susceptor shaft 41. The vertical gas flow path 44 is formed between the susceptor shaft 41 and the thermal barrier 42. After the rotary driving gas is injected through the gas introduction path 43, And then communicates with the first and second gas flow paths to be described later.

In this embodiment, the main disc 31 is formed in a substantially disc shape, and the main disc 31 is provided with a plurality of receiving pockets 31a, which are spaces formed by cutting from the upper surface, The sub disc 33 and the gas injection table 32 are accommodated in the pocket 31a.

A coupling hole 31b is formed at an edge of the receiving pocket 31a of the main disk 31 so as to be spaced apart along the periphery of the main disk 31. The coupling hole 31b is connected to the gas injection So that the table 32 is fastened.

A plurality of exhaust holes 31c are formed at predetermined intervals along the outer periphery of the receiving pocket 31a of the main disk 31. A rotary driving gas supplied through a gas flow path, The disk 33 is rotated and then exhausted to the outside through the exhaust hole.

The rotation driving gas may be an inert gas to prevent the reaction gas supplied through the gas supply unit 50 from being deposited on the main disk 31 or the sub disk 33.

A second gas passage 46 is formed in the main disc 31 at a lower portion of the receiving pocket 31a. The second gas passage 46 is configured to communicate with the first gas passage 45 formed in the susceptor bottom disk 34 to be described later, Is supplied to the receiving pocket 31a and then injected through a gas supply hole of the gas injection table 32 described later.

The main disk 31 may be directly fixed to the susceptor shaft 41 that supports and rotates the susceptor 30. In the present embodiment, the main disk 31 is fixed to the susceptor bottom disk 34 to the susceptor shaft 41.

3, the susceptor bottom disk 34 is fixed to the susceptor shaft 41, and the susceptor bottom disk 34 is provided with a vertical gas passage 41 formed in the susceptor shaft 41, And a first gas passage 45 communicating with the first gas passage 44 and supplied with rotational driving gas. The main disk 31 may be detachably fastened to the susceptor bottom disk 34.

The first gas flow path 45 and the second gas flow path 46 may be formed toward the center of the receiving pocket 31a as shown in Figure 5A, May be formed along the tangential direction of the pocket 31a and extend to extend to the end of the main disk 31. The end of the main disk 31 is configured to be sealed.

The sub disc (33) is accommodated in the receiving pocket (31a) of the main disc (31). The sub-disc 33 has a seating groove (not shown) formed in an upper surface thereof, and the substrate W is seated in the seating groove.

In the present embodiment, the sub disk 33 is lifted and rotated by the gas injection table 32.

The gas injection table 32 is disposed between the main disk 31 and the sub disk 33. The gas injection table 32 is formed substantially in the shape of a disk and is fastened to the main disk 31 by inserting a fastening means such as a fastening bolt or a fastening pin into the fastening hole 32a formed at a predetermined distance from the outer circumference. .

The gas injection holes 32b and 32c are formed in the gas injection table 32 to communicate with the receiving pockets 31a. Here, the gas supply hole includes a floating gas supply hole 32b and a rotating gas supply hole 32c (see FIG. 6B).

The floating gas supply hole 32b is formed perpendicular to the thickness direction of the gas injection table 32 so that the rotary driving gas supplied to the receiving pocket 31a is injected through the floating gas supply hole 32b The subdisks 33 are lifted from the gas injection table 32 by pushing up the subdisks 33 disposed above the gas injection table 32.

6C, the rotation gas supply hole 32c is formed so as to be inclined with respect to the thickness direction of the gas injection table 32, so that the rotational driving gas supplied to the receiving pocket 31a is rotated And is injected through the gas supply hole 32c to rotate the floating sub-disc 33.

7A and 7B, the floating gas supply hole 32b and the rotation gas supply hole 32c are not formed separately but are formed in a spiral long slit shape, A through-hole may be formed to be integrally formed.

8, a lower step 32d is formed on the upper surface of the gas injection table 32 toward the outer circumferential surface of the gas injection table 32. A lower surface of the sub- And the step 33a corresponding to the step 32d can be formed. Thus, the rotary drive gas is exhausted through the exhaust hole 31c without being directed toward the center of the sub disc 33 by the steps 32d and 33a, and the gas injection surface of the gas injection table 32 And the sub-disc 33 are closely contacted with each other, so that the sub-disc 33 can be easily lifted and rotated by using a small amount of rotational driving gas.

The main disk 31 and the sub disk 33 are preferably made of a material having high temperature and durability capable of induction heating. The main disk 31 and the sub disk 33, which are heated by the induction heating method, The uniform temperature is transferred to the substrate W mounted on the substrate 33, and the uniformity of the thin film can be prevented from decreasing due to the stable flow of the gas during crystal growth, and the thin film growth rate can be improved.

In addition, by separating the main disk 31 and the sub disk 33, only the sub disk 33, which is relatively vulnerable to deposition of contaminants due to vapor phase reaction and parasitic deposition, can be separately cleaned, The cleaning cost and the cleaning cycle can be increased by selecting a material capable of suppressing the etching and contaminant deposition.

An edge cover or a center cover may be provided on the upper surface of the main disk 31 to protect the main disk 31 from deposition of contaminants to thereby improve the cleaning cost and cleaning cycle of the main disk, You can increase the period.

It is also possible to simplify the design of the gas injection table 32 and the sub disc 33 and remove the lower step and pocket of the substrate W on the rim of the seating groove on the upper surface of the sub disc 33, The temperature delivered directly or indirectly becomes uniform, and stable flow of the gas during the crystal growth on the heated substrate can prevent the uniformity of the thin film from being lowered and improve the thin film growth rate.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. It will be apparent to those of ordinary skill in the art.

One ; Organometallic Chemical Vapor Deposition Device
10: substrate accommodating chamber
20: Heater
30: susceptor
40: Sealing part
50: gas supply part

Claims (7)

A substrate receiving chamber including a chamber lid and an outer wall portion and a bottom flange portion,
A susceptor disposed in the substrate accommodating chamber for accommodating a plurality of substrates and having a gas flow path formed therein and rotating the plurality of substrates by a rotary driving gas supplied through the gas flow path,
And a heater for heating a substrate placed on the susceptor,
Wherein the susceptor comprises: a main disk on which a substrate is placed; a main disk in which a plurality of receiving pockets for accommodating the sub disk and communicating with the gas flow path are formed; and a vertical gas flow path for rotating the main disk, And a susceptor shaft formed on the susceptor.
The method according to claim 1,
Wherein the susceptor includes a gas injection table disposed between the main disk and the sub disk and having a gas supply hole communicating with the accommodating pocket.
3. The method of claim 2,
Wherein the gas supply hole of the gas injection table
A floating gas supply hole formed vertically in the thickness direction of the gas injection table to float the sub disk by supplied gas,
And a rotating gas supply hole formed to be inclined with respect to the thickness direction of the gas injection table and rotating the sub disc by the supplied gas.
The method of claim 3,
Wherein the floating gas supply hole and the rotation gas supply hole are integrally formed.
The method according to claim 1,
Wherein the susceptor has a susceptor bottom disk fixedly mounted on the susceptor shaft,
Wherein the main disk is detachably coupled to the susceptor bottom disk.
3. The method of claim 2,
A lower step is formed on the upper surface of the gas injection table toward the outer peripheral surface,
And a step corresponding to a step of the gas injection table is formed on the bottom surface of the sub disk.
The method according to claim 1,
Wherein the rotary driving gas is an inert gas.

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