KR101513504B1 - Substrate processing apparatus - Google Patents

Abstract

According to an embodiment of the present invention, there is provided a substrate processing apparatus comprising: a substrate processing apparatus which includes a substrate processing apparatus for performing a substrate processing process on a substrate, A chamber in which a supply port is formed on the opposite side of the passage; A susceptor installed in the inner space and disposed below the substrate to heat the substrate; And a diffusion member disposed between the susceptor and an inner wall of the chamber and positioned at an outlet side of the supply port and having a plurality of diffusion holes for diffusing the gas supplied through the supply port.

Description

[0001] SUBSTRATE PROCESSING APPARATUS [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a substrate processing apparatus, and more particularly, to a substrate processing apparatus capable of ensuring productivity and quality of a substrate by maintaining a laminar flow of a substrate through a diffusion plate and an exhaust plate provided on one side and the other side of the chamber .

In general, efforts have been made to improve devices and processes for forming high-quality thin films on semiconductor substrates in the manufacture of semiconductor devices, and several methods have been used to form thin films using surface reactions of semiconductor substrates .

Such methods include vacuum evaporation deposition, molecular beam epitaxy (MBE), low-pressure chemical vapor deposition, organometallic chemical vapor deposition, plasma Chemical vapor deposition (CVD), including plasma-enhanced chemical vapor deposition (CVD), and atomic layer epitaxy (ALE).

Among them, atomic layer crystal growth (ALE) has been extensively studied in semiconductor deposition and inorganic electroluminescent display devices, and recently, atomic layer deposition (ALD) is used to deposit various material layers.

Atomic layer deposition (ALD) is a method of depositing a thin film on the surface of a substrate by supplying two or more reactive gas sources sequentially and discontinuously to each other on a semiconductor substrate. A plurality of reactive gases adsorbed on the substrate surface react with atoms A thin film is grown on a layer-by-layer basis and repeatedly performed to form a thin film having a desired thickness.

For example, a first reaction gas is supplied onto a substrate to adsorb a first reaction gas onto the substrate. After the first reaction gas is adsorbed on the substrate, the purge gas is supplied or the gas in the reaction chamber is forcibly removed to remove the adsorbed remaining first reaction gas or byproduct. A second reactive gas is then supplied onto the substrate, and a second reactive gas reacts with the first reactive gas adsorbed onto the substrate and is deposited on the atomic layer.

At this time, the reaction is terminated after all of the first reaction gas layers adsorbed on the substrate react with the second reaction gas. Thereafter, the purge gas is supplied again or the gas in the reaction chamber is forcibly removed to react and remove the remaining second reaction gas or byproduct. This cycle is repeated until a thin film of desired thickness is deposited. This cycle may utilize not more than two reactant gases but three or more reactant gases and may include additional purge steps.

A deposition apparatus suitable for a general chemical vapor deposition method is designed to form a thin film by simultaneously supplying reactive gases so that a thin film is formed by supplying a reactive gas discontinuously or a reactive gas supplied sequentially is prevented from causing a gas phase reaction in the reactor It was not suitable for the method of removing and reacting through purge. Further, in the vapor deposition apparatus in which the gas is supplied on the semiconductor substrate from the top to the bottom, generally, a shower head is used to supply a uniform reactive gas onto the substrate. However, such a structure complicates the flow of the process gas and requires a large-sized reactor, so that it is difficult to rapidly change the supply of the reactant gas.

Korean Patent Registration No. 10-1212514. December 14, 2012.

It is an object of the present invention to provide a laminar flow of a gas flowing on a substrate.

Another object of the present invention is to realize an ideal laminar flow of the substrate to improve the quality and productivity of the substrate.

Other objects of the present invention will become more apparent from the following detailed description and the accompanying drawings.

According to an embodiment of the present invention, there is provided a substrate processing apparatus comprising: a substrate processing apparatus which includes a substrate processing apparatus for performing a substrate processing process on a substrate, A chamber in which a supply port is formed on the opposite side of the passage; A susceptor installed in the inner space and disposed below the substrate to heat the substrate; And a diffusion member disposed between the susceptor and an inner wall of the chamber and positioned at an outlet side of the supply port and having a plurality of diffusion holes for diffusing the gas supplied through the supply port.

The substrate processing apparatus includes an exhaust port formed on the opposite side of the supply port and exhausting the gas; An exhaust member disposed between the susceptor and an inner wall of the chamber and positioned at an opposite side of the supply port and having a plurality of exhaust holes for exhausting the gas that has passed through the substrate to the exhaust port; And a lifting member for lifting the exhaust member.

The elevating member includes: a cylinder rod connected to a lower portion of the exhausting member; And a cylinder for lifting and lowering the cylinder rod.

The exhaust member being in a standby position capable of loading the substrate by the cylinder into the chamber through the passage; And a process position for partitioning the upper portion of the susceptor and the passage to diffuse the process gas.

The diffusion holes and the exhaust holes are arranged at predetermined intervals from each other, and may have a circular or elongated shape.

The substrate processing apparatus may further include an auxiliary diffusion plate spaced apart from the diffusion member and positioned on the supply port, the auxiliary diffusion plate having a plurality of auxiliary diffusion holes arranged to be shifted from the diffusion holes.

The distance between the diffusion plate and the exhaust plate may be constant along the longitudinal direction of the diffusion plate and the exhaust plate.

The susceptor has a heating region for heating the substrate, and the heating region may be eccentrically positioned with respect to the center of the susceptor and disposed closer to the passage than the supply port.

Wherein the diffusion member includes a diffusion body having a top surface that is lower than an upper surface of the susceptor and which faces the side surface of the susceptor and the inner wall of the chamber and a diffusion plate protruded from an upper surface of the diffusion body, Wherein the exhaust member includes an exhaust body having an upper surface located lower than an upper surface of the susceptor in a state of being raised and lowered in contact with a side surface of the susceptor and an exhaust plate protruding from an upper surface of the exhaust body, The inlet side of the exhaust port may be located on the bottom surface of the spacing space formed between the exhaust plate and the inner wall of the chamber.

Wherein the chamber has a top open shape, the substrate processing apparatus further comprising: a chamber cover provided on an open top of the chamber and having a first mounting groove on an inner surface thereof; An insulator inserted into the first insertion groove and having a second installation groove on an inner surface thereof; Further comprising a top electrode inserted in the second mounting groove and having an antenna for generating a plasma in the internal space through a current supplied from the outside, wherein the chamber cover, the insulator and the topelectrode The inner space may be partitioned to provide a reaction space for the substrate.

According to an embodiment of the present invention, it is possible to provide laminar flow of the gas supplied through the supply port by using the diffusion plate and the exhaust plate installed in the inner space of the chamber. In addition, the heating region for heating the substrate by loading the substrate is disposed closer to the passage than the supply port, so that uniform gas can be supplied onto the substrate, thereby improving the quality and productivity of the substrate.

1 is a schematic view of a semiconductor manufacturing facility according to an embodiment of the present invention.
Fig. 2 is a view schematically showing the substrate processing apparatus shown in Fig. 1. Fig.
3 is an exploded perspective view of the substrate processing apparatus shown in Fig.
Figs. 4 and 5 are views showing a standby position and a process position of the exhaust plate shown in Fig. 2. Fig.
Fig. 6 is a view showing a heating region of the susceptor shown in Fig. 2. Fig.
Fig. 7 is a view showing a gas flow state of the substrate processing apparatus shown in Fig. 2. Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described below. The embodiments are provided to explain the present invention to a person having ordinary skill in the art to which the present invention belongs. Accordingly, the shape of each element shown in the drawings may be exaggerated to emphasize a clearer description. Although the substrate W will be described below as an example, the present invention can be applied to various objects to be processed.

1 is a schematic view of a semiconductor manufacturing facility according to an embodiment of the present invention. As shown in FIG. 1, the semiconductor manufacturing facility 100 generally includes a process facility 120 and an equipment front end module 110 (EFEM). The facility front end module 110 is mounted in front of the process facility 120 to transfer the substrate W between the container containing the substrates W and the process facility.

The substrate W is subjected to a predetermined process in the process facility 120. The process facility 120 may comprise a transfer chamber 130, a load lock chamber 140, and a plurality of substrate processing apparatuses 10 for performing the process. The transfer chamber 130 has a generally polygonal shape when viewed from the top and the load lock chamber 140 and the substrate processing apparatuses 10 are respectively installed on the sides of the transfer chamber 130. The transfer chamber 130 may have a rectangular shape, and two substrate processing apparatuses 10 may be disposed on the side of the transfer chamber 130, respectively.

The load lock chamber 140 is located on the side of the transfer chamber 130 that is adjacent to the facility front end module 110. The substrate W is temporarily loaded into the load lock chamber 140 and then loaded into the process facility 120 to perform the process. After the process is completed, the substrate W is unloaded from the process facility 120, (140). ≪ / RTI > The transfer chamber 130 and each substrate processing apparatus 10 are maintained in vacuum and the load lock chamber 130 is switchable to vacuum and atmospheric pressure. The load lock chamber 130 prevents foreign contaminants from entering the transfer chamber 140 and the substrate processing apparatuses 10 and prevents exposure of the substrate W to the atmosphere during transfer of the substrate W The growth of the oxide film on the substrate W can be prevented.

A gate valve (not shown) may be installed between the load lock chamber 140 and the transfer chamber 130 and between the load lock chamber 140 and the apparatus front end module 110, (Transfer robot). The substrate handler 135 transfers the substrate W between the load lock chamber 140 and the substrate processing apparatuses 10. For example, the substrate handler 135 provided in the transfer chamber 130 simultaneously transfers the substrate W to the substrate processing apparatus 10 disposed on the side of the transfer chamber 130 through the first and second blades, respectively Can be loaded.

Fig. 2 is a view schematically showing the substrate processing apparatus shown in Fig. 1, and Fig. 3 is an exploded perspective view of the substrate processing apparatus shown in Fig. As shown in FIGS. 2 and 3, the chamber 20 can transfer the substrate W through the passage 22 formed at one side to perform the process on the substrate W. The chamber 20 has an open top and a chamber lid 12 is installed at the open top of the chamber 20. The chamber cover 12 has a first installation groove 13 formed on the inner surface thereof and an insulator 15 inserted into the first installation groove 13. The insulator 15 has a second mounting groove 16 formed on the inner surface thereof and a second mounting groove 16 provided with a top electrode 18 for generating plasma in the inner space 3 of the chamber 20 have.

The lower surface of the topelectrode 18 is aligned with the upper surface of the susceptor 30 and an antenna 17 is provided therein to supply a high frequency current from the outside. The open top of the chamber 20 can be closed by the chamber lid 12, the insulator 15 and the top electrode 18 to form the internal space 3 and the chamber lid 12 is closed by the chamber 20 And the upper portion of the chamber 20 can be opened when the chamber 20 is being repaired.

The chamber 20 has an internal space 3 for processing the substrate W, and the internal space 3 may have a rectangular parallelepiped shape. The susceptor 30 is installed in the inner space 3 and is disposed below the substrate W to heat the substrate W. One or more supply ports 25 are formed on the opposite side of the passage 22 and the process gas can be supplied to the interior of the chamber 20 through the supply port 25. The diffusion member 40 is disposed between the susceptor 30 and the inner wall of the chamber 20 and is disposed in front of the supply port 25 to supply a plurality of diffusions for diffusing the process gas supplied through the supply port 25, Holes (45).

The diffusion member 40 has a diffusion body 42 and a diffusion plate 44 and the diffusion body 42 is filled in the spaced space between the susceptor 30 and the inner wall of the chamber 20, ) And the inner wall of the chamber 20. The diffusion plate 44 protrudes from the upper surface of the diffusion body 42 and is disposed outside the diffusion body 42 and contacts the lower surface of the insulator 15. The diffusion holes 45 are formed in the diffusion plate 44.

At least one exhaust port 28 is formed on the opposite side of the supply port 25 to exhaust unreacted gas and reaction by-products that have passed through the substrate W. [ The exhaust member 50 is installed between the susceptor 30 and the inner wall of the chamber 20 in which the passage 22 is formed and is capable of ascending and descending so as to maintain the flow of the process gas passing through the substrate W A plurality of exhaust holes 55 are formed. The diffusion member 40 and the exhaust member 50 may have a symmetrical shape, and the diffusion holes 45 and the exhaust holes 55 may be formed in parallel with each other.

The exhaust member 50 includes an exhaust body 52 and an exhaust plate 54. The exhaust body 52 is installed in a spaced space between the susceptor 30 and the inner wall of the chamber 20, 30 from the inner wall of the chamber 20 in contact therewith. The inlet side (or top) of the exhaust port 28 is located on the bottom surface of the spacing space formed between the exhaust body 42 and the inner wall of the chamber 20.

For example, the cylinder rod 57 is connected to the lower portion of the exhaust member 50, and the cylinder rod 57 can be lifted and lowered by the cylinder 58 and moved up and down together with the exhaust member 50. The exhaust member 50 and the diffusion member 40 are symmetrical to each other and a plurality of exhaust holes 55 and diffusion holes 45 are formed at predetermined intervals on the exhaust plate 54 and the diffusion plate 44 do. The exhaust holes 55 and the diffusion holes 45 may have a circular or elongated shape.

The diffusion member 40 and the exhaust member 50 are respectively filled in the spacing space between the susceptor 30 and the inner wall of the chamber 20 and the chamber lid 12, the insulator 15, The upper portion of the chamber 20 is closed by the upper chamber 18 to partition the inner space 3 of the chamber 20 to form a reaction space 5 in which the process gas and the substrate W react.

Since the diffusion member 40 and the exhaust member 50 are disposed perpendicular to the inner wall of the adjacent chamber 20 and the inner wall of the chamber 20 is disposed substantially in parallel with the flow of the process gas, And has a rectangular parallelepipedal cross-section. Particularly, since the exhaust member 50 is disposed on the side of the passage 22, it is possible to eliminate the asymmetry of the reaction space 5 due to the passage 22 and to prevent unevenness of the process caused by the passage 22 have. In other words, the passageway 22 is formed at one side of the chamber 20 so that the substrate W can enter and exit the interior of the chamber 20 through the passageway 22, The inner space has an inevitable limit of asymmetry. However, by partitioning the passage 22 from the reaction space 5 through the exhaust plate 50, the reaction space 5 can have symmetry.

That is, the process gas is supplied into the chamber 20 through the supply port 25 in the reaction space 5 of the chamber 20, and the process gas supplied into the chamber 20 through the supply port 25 And diffused by passing through the diffusion holes 45 formed in the diffusion plate 44. The diffused process gas passes through the substrate W in the reaction space 5 and the unreacted gas and the gas by-products are exhausted through the exhaust holes 55 formed in the exhaust plate 54 and the exhaust port 28 . Accordingly, it is possible to maintain a laminar flow of the process gas through the exhaust holes 55 and the diffusion holes 45 formed in the exhaust plate 54 and the diffusion plate 44, and to supply a uniform process gas to the entire surface of the substrate W .

Since the upper surface of the diffusion body 42 is disposed lower than the upper surface of the susceptor 30, the upper portion of the diffusion body 42 in the reaction space 5 has a height greater than the upper portion of the susceptor 30, This allows the process gas that has passed through the diffusion holes 45 to have a space that can diffuse at the top of the diffusion body 42. Likewise, since the upper surface of the exhaust body 52 is disposed lower than the upper surface of the susceptor 30, the upper portion of the exhaust body 52 in the reaction space 5 has a height larger than that of the upper portion of the susceptor 30, Thus, the process gas passing through the upper portion of the susceptor 30 can have a space that can flow at the upper portion of the exhaust body 52. The process gas supplied through the diffusion member 40 and exhausted through the exhaust member 50 can exhibit a uniform flow regardless of the position along the longitudinal direction of the diffusion member 40 or the exhaust member 50 .

Further, an auxiliary diffusion plate 60 may be provided on the supply port 25. The auxiliary diffusion plate 60 is spaced apart from the diffusion plate 40 by a predetermined distance and a plurality of auxiliary diffusion holes 65 are formed in the same manner as the diffusion plate 44. The auxiliary diffusing hole 65 and the diffusing hole 45 are formed to be shifted from each other so that the process gas that has passed through the auxiliary diffusing hole 65 is diffused again through the diffusion hole 45, So that a uniform process gas can be supplied.

Figs. 4 and 5 are views showing a standby position and a process position of the exhaust plate shown in Fig. 2. Fig. A cylinder rod 57 is connected to a lower portion of the exhaust plate 50, and the cylinder rod 57 can be raised and lowered by a cylinder 58. 4, when the substrate W is loaded into the chamber 20, the cylinder rod 57 is lowered to dispose the exhaust plate 50 together with the exhaust gas (The " standby position ").

5, when the substrate W is to be processed after the substrate W is loaded, the gate valve provided outside the passage 22 is closed, the cylinder 58 is closed, So that the exhaust plate 50 can be raised together (the 'process position'). The auxiliary diffuser plate 60 and the diffuser plate 44 and the exhaust plate 54 are disposed at substantially the same height and the process gas dispersed through the auxiliary diffuser plate 60 and the diffuser plate 44 The laminar flow can be maintained by the exhaust plate 54 through the substrate W. [

FIG. 6 is a view showing a heating region of the susceptor shown in FIG. 2, and FIG. 7 is a view showing a gas flow state of the substrate processing apparatus shown in FIG. As described above, the susceptor 30 is installed in the inner space 3 of the chamber 20 and heats the substrate W loaded thereon. The substrate W may be loaded on the seating groove 31 by the lift pins 32. The substrate W may be placed on the susceptor 30, have.

6 and 7, the susceptor 30 has a heating region 35 for heating the substrate W, and the heating region 35 corresponds to the seating groove 31 in which the substrate is placed . A heater (not shown) may be provided on the heating zone 35 and the heating zone 35 is disposed closer to the passageway 22 than the supply port 25. In other words, the distance d ₁ between the center C of the heating zone 35 and the passage 22 is less than the distance d ₂ between the center C of the heating zone 35 and the supply port 25 Big. The process gas supplied through the supply port 25 sequentially passes through the auxiliary diffusion hole 65 and the diffusion hole 45 as the heating zone 35 is disposed closer to the passage 22 than the supply port 25 It is possible to provide an easy distance and time for forming a laminar flow toward the substrate W. [

The process gas supplied through the supply port 25 is formed such that the auxiliary diffusion hole 65 and the diffusion hole 45 are shifted from each other and the process gas that has primarily passed through the auxiliary diffusion hole 65 is diffused into the diffusion hole 45, Lt; / RTI > That is, the process gas can form a laminar flow on the substrate W and flow to supply a uniform process gas. In addition, the exhaust gas can be exhausted while maintaining the laminar flow of the process gas through the exhaust holes 55 formed in the exhaust plate 50, so that the uniformity of the edge portion and the center portion of the substrate W can be maintained.

Particularly, since the reaction space 5 has a rectangular cross section, the same distance can be maintained from the diffusion plate 44 to the exhaust plate 54, and the process gas can be supplied to the diffusion plate 44 ) To the exhaust plate 54. [0051] As shown in Fig. On the other hand, when the reaction space 5 has a circular cross-section, the distance from the diffuser plate 44 to the exhaust plate 54 varies depending on the position, so that the process gas is uniformly laminar in the reaction space 5 flow.

Accordingly, the substrate processing apparatus 10 according to the present invention is configured such that the exhaust port 28 is spaced apart from the substrate so as to eliminate the bias of the process gas in the conventional substrate processing apparatus, so that the volume of the internal space 3 of the chamber 20 becomes large It is possible to compensate for the problem that the amount of the process gas required for the process according to the first embodiment increases and the process cost increases and the process time required for performing deposition of the substrate W becomes longer. It is also possible to form a laminar flow of the process gas in the inner space of the chamber 20 by using the diffusion member 40 and the auxiliary diffusion plate 60 and the exhaust member 50 and to minimize the flow space of the gas, The efficiency and quality of the process can be improved.

Although the present invention has been described in detail by way of preferred embodiments thereof, other forms of embodiment are possible. Therefore, the technical idea and scope of the claims set forth below are not limited to the preferred embodiments.

3: inner space 5: reaction space
10: substrate processing apparatus 20: chamber
22: passage 25: supply port
28: exhaust port 30: susceptor
31: seat groove 35: heating zone
40: diffusion member 45: diffusion hole
50: exhaust member 55: exhaust hole
60: auxiliary diffusion plate 65: auxiliary diffusion hole
100: Semiconductor manufacturing facility 110: EFEM
120: Process equipment 130: Transfer chamber
140: load lock chamber

Claims (10)

A chamber in which a substrate is transported through a passage formed at one side and which provides a rectangular parallelepiped internal space in which the substrate is processed and a supply port for supplying gas toward the substrate is formed on the opposite side of the passage;
A susceptor installed in the inner space and disposed below the substrate to heat the substrate;
A diffusion member disposed between the susceptor and an inner wall of the chamber and positioned at an outlet side of the supply port and having a plurality of diffusion holes for diffusing the gas supplied through the supply port;
An exhaust port formed on an opposite side of the supply port and exhausting the gas;
An exhaust member disposed between the susceptor and an inner wall of the chamber and positioned at an opposite side of the supply port and having a plurality of exhaust holes for exhausting the gas that has passed through the substrate to the exhaust port; And
And an elevating member for ascending and descending the exhaust member,
The susceptor having a heating region on which the substrate is placed and heating the substrate,
Wherein the heating region is eccentrically positioned with respect to a center of the susceptor so as to be closer to the passage than the supply port,
Wherein the exhaust member is movable by the elevating member to a standby position capable of loading the substrate into the chamber through the passage and to a process position where the gas is diffused by partitioning the upper portion of the susceptor and the passage, Processing device. delete The method according to claim 1,
The elevating member
A cylinder rod connected to a lower portion of the exhaust member; And
And a cylinder for lifting and lowering the cylinder rod. A chamber in which a substrate is transported through a passage formed at one side and which provides a rectangular parallelepiped internal space in which the substrate is processed and a supply port for supplying gas toward the substrate is formed on the opposite side of the passage;
A susceptor installed in the inner space and disposed below the substrate to heat the substrate;
A diffusion member disposed between the susceptor and an inner wall of the chamber and positioned at an outlet side of the supply port and having a plurality of diffusion holes for diffusing the gas supplied through the supply port;
An exhaust port formed on an opposite side of the supply port and exhausting the gas;
An exhaust member disposed between the susceptor and an inner wall of the chamber and positioned at an opposite side of the supply port and having a plurality of exhaust holes for exhausting the gas that has passed through the substrate to the exhaust port; And
And an elevating member for ascending and descending the exhaust member,
Wherein the exhaust member is movable by the elevating member to a standby position capable of loading the substrate into the chamber through the passage and to a process position where the gas is diffused by partitioning the upper portion of the susceptor and the passage, Processing device. The method according to claim 1 or 4,
Wherein the diffusion holes and the exhaust holes are arranged at predetermined intervals from each other and have a circular or elongated shape. A chamber in which a substrate is transported through a passage formed at one side and which provides a rectangular parallelepiped internal space in which the substrate is processed and a supply port for supplying gas toward the substrate is formed on the opposite side of the passage;
A susceptor installed in the inner space and disposed below the substrate to heat the substrate;
A diffusion member disposed between the susceptor and an inner wall of the chamber and positioned at an outlet side of the supply port and having a plurality of diffusion holes for diffusing the gas supplied through the supply port; And
And an auxiliary diffusion plate spaced apart from the diffusion member and positioned on the supply port, the auxiliary diffusion plate having a plurality of auxiliary diffusion holes arranged to be different from the diffusion holes. The method according to claim 1 or 4,
Wherein the distance between the diffusion member and the exhaust member is constant along the longitudinal direction of the diffusion member and the exhaust member. delete A chamber in which a substrate is transported through a passage formed at one side and which provides a rectangular parallelepiped internal space in which the substrate is processed and a supply port for supplying gas toward the substrate is formed on the opposite side of the passage;
A susceptor installed in the inner space and disposed below the substrate to heat the substrate;
A diffusion member disposed between the susceptor and an inner wall of the chamber and positioned at an outlet side of the supply port and having a plurality of diffusion holes for diffusing the gas supplied through the supply port;
An exhaust port formed on an opposite side of the supply port and exhausting the gas;
An exhaust member disposed between the susceptor and an inner wall of the chamber and positioned at an opposite side of the supply port and having a plurality of exhaust holes for exhausting the gas that has passed through the substrate to the exhaust port; And
And an elevating member for ascending and descending the exhaust member,
Wherein the diffusion member includes a diffusion body having a top surface that is lower than an upper surface of the susceptor and which faces the side surface of the susceptor and the inner wall of the chamber and a diffusion plate protruded from an upper surface of the diffusion body, In addition,
The exhaust unit includes an exhaust body having an upper surface located lower than an upper surface of the susceptor in a state of being raised and lowered in contact with a side surface of the susceptor, and an exhaust plate protruded from an upper surface of the exhaust body to form the exhaust holes ,
And an inlet side of the exhaust port is located on a bottom surface of a spacing space formed between the exhaust plate and the inner wall of the chamber. Wherein a substrate is transported through a passage formed on one side and provides a rectangular parallelepiped internal space in which processing is performed on the substrate and a supply port for supplying gas toward the substrate is provided on an opposite side of the passage, Chamber;
A susceptor installed in the inner space and disposed below the substrate to heat the substrate; And
A diffusion member disposed between the susceptor and an inner wall of the chamber and positioned at an outlet side of the supply port and having a plurality of diffusion holes for diffusing the gas supplied through the supply port;
A chamber cover provided on an open top of the chamber and having a first mounting groove on an inner surface thereof;
An insulator inserted into the first insertion groove and having a second installation groove on an inner surface thereof; And
And a top electrode inserted into the second mounting groove and having an antenna for generating a plasma in the internal space through a current supplied from the outside,
And the chamber cover, the insulator, and the top electrode to divide the internal space to provide a reaction space for the substrate.

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