KR101267819B1 - Substrate processing apparatus - Google Patents

Abstract

The plasma generating module according to the present invention is provided with a body in which a plasma generation space in which plasma is generated, an electrode installed in the body, and installed in the body, at least one side of which is exposed to the plasma generating space, and the other side of which is in contact with the electrode. And a dielectric member.
Therefore, according to embodiments of the present invention, direct contact between the electrode and the body is blocked by the dielectric member, so that arcing is suppressed. In addition, when a plasma is generated, a sufficient amount of electric field is generated on the surface of the dielectric member, so that the free movement distance of electrons can be suppressed from being reduced even at a high pressure such as atmospheric pressure. Therefore, stable discharge is possible even at a high pressure such as atmospheric pressure, and there is an advantage in that a substrate processing process using radicals is easy.

Description

Plasma generating module and substrate processing apparatus including the same {SUBSTRATE PROCESSING APPARATUS}

The present invention relates to a plasma generation module that is easy to generate plasma, and a substrate processing apparatus including the same.

Substrate processing apparatus for generating a remote plasma (Remote plasma) is to process the substrate by using a radical, the substrate is disposed in the chamber, the substrate mounting portion for placing the substrate and the substrate mounting portion corresponding to generate a remote plasma And a plasma generating module. Here, the plasma generating module is made of a cylindrical shape, and is composed of a grounded body, an electrode inserted into the body and supplied with power for plasma generation.

On the other hand, in the conventional substrate processing apparatus, the process using the remote plasma can be performed only at a low pressure. This is because when a plasma is generated at a high pressure such as atmospheric pressure, an arc is generated between the body and the electrode, and a problem in which a general glow discharge cannot be generated at a high pressure is generated. In addition, the increase in pressure acts as a factor to lower the electron free path (mean free path). At this time, a strong electric field is required to compensate for the energy loss of electrons and ions due to the reduction of the mean free path, but an excessively large voltage is required for this purpose. Therefore, the pressure process range using the remote plasma is limited, and there is a difficulty in the process in the high pressure range such as atmospheric pressure.

Korean Patent No. 10-0489624 discloses a technique for a plasma generating apparatus including a gas injection port through which a gas for treating a target object passes as two electrodes provided to face each other and a region between the two electrodes.

Korean Patent Registration No. 10-0489624

One technical problem of the present invention is to provide a plasma generating module and a substrate processing apparatus including the same.

Another object of the present invention is to provide a plasma generating module and a substrate processing apparatus including the same.

Another technical problem of the present invention is to provide a plasma generating module and a substrate processing apparatus including the same.

The plasma generating module according to the present invention includes a body having a plasma generating space therein for generating plasma therein, an electrode provided in the body, and installed in the body, at least one side of which is exposed to the plasma generating space, and the other side of the plasma generating module And a dielectric member in contact.

The body is formed extending in the vertical direction,

The electrode is provided to be spaced apart from an inner wall of the body surrounding the plasma generating space in the plasma generating space.

An injection hole communicating with the plasma generating space is provided at one end of the body.

The body extends in the width direction, and the electrode is installed to be spaced apart from an inner wall of the body surrounding the plasma generating space in the plasma generating space.

The inner circumferential surface of the dielectric member is provided to surround the electrode so as to contact the outer circumferential surface of the electrode.

The body is formed extending in the width direction,

The electrode is installed to be spaced apart from the plasma generating space in the body,

The dielectric member is disposed between the plasma generating space and the electrode so that one side is exposed to the plasma generating space and the other side is in contact with the electrode.

An injection hole is provided in the body to communicate with the plasma generating space,

A pumping space penetrating the body in the vertical direction is provided,

The capping space is spaced apart from one side of at least one of the electrode and the dielectric member.

The body is grounded.

The plasma generating space is formed to extend in the vertical direction.

A substrate processing apparatus according to the present invention includes a chamber having an internal space, a substrate placement portion disposed in the chamber, opposed to a substrate placement portion and a substrate placement portion, and generating a plasma to generate a plasma. The module has a plasma generating space in which a plasma is generated therein, a grounded body, a dielectric member disposed on at least one side of the plasma generating space of the body in the body, and at least one surface of which is exposed to the plasma generating space and the dielectric material. And an electrode installed to be in contact with the other surface of the member.

At least one side of the electrode and the dielectric member is spaced apart, and includes a pumping space provided to penetrate the body in the vertical direction.

According to embodiments of the present invention, direct contact between the electrode and the body is blocked by the dielectric member, so that arcing is suppressed. In addition, when a plasma is generated, a sufficient amount of electric field is generated on the surface of the dielectric member, so that the free movement distance of electrons can be suppressed from being reduced even at a high pressure such as atmospheric pressure. Therefore, a stable glow discharge is possible even at a high pressure such as atmospheric pressure, and there is an advantage in that a substrate treating process using radicals is easy.

Further, according to embodiments of the present invention, the cylindrical plasma generating module is easy to process a circular substrate or to process a local region of the substrate. In the case of the flat plasma generating module, the linear uniformity of the raw material, plasma, and radicals to be injected is excellent, and the uniformity of substrate processing is improved. Therefore, in the case of the flat panel plasma module, there is an advantage in that the process of continuously processing the substrate in one direction or the process of horizontally moving the substrate formed in one direction.

1 illustrates a substrate processing apparatus including a plasma generating module according to a first embodiment of the present invention.
2 is a cross-sectional view showing a plasma generating module according to a first embodiment of the present invention
3 is a top view of the plasma generating module according to the first embodiment of the present invention;
4 illustrates a substrate processing apparatus including a plasma generating module according to a second embodiment of the present invention.
5 illustrates a substrate processing apparatus including a plasma generation module according to a third embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. Wherein like reference numerals refer to like elements throughout.

1 is a diagram illustrating a substrate processing apparatus including a plasma generating module according to an embodiment of the present invention. 2 is a cross-sectional view showing a plasma generating module according to a first embodiment of the present invention. 3 is a top view of the plasma generating module according to the first embodiment of the present invention.

1 and 2, a substrate processing apparatus includes a chamber 100 having an internal space, a substrate support module 200 supporting a substrate S introduced into the chamber 100, and a substrate outside the chamber 100. It is disposed corresponding to the upper side of the support module 200, and includes a plasma generating module 300 extending in the vertical direction, and a raw material supply pipe 500 for supplying the process raw material into the plasma generating module 300. In addition, although not shown, it includes a fixing member for supporting and fixing the plasma generating module 300 on the chamber 100. The substrate treating apparatus according to the embodiment may be applied to, for example, an apparatus for treating the substrate S by an atomic layer deposition (ALD) method under atmospheric pressure, but is not limited thereto and may be applied to various apparatuses for applying plasma.

The chamber 100 is manufactured in the shape of a square cylinder having an empty inside, and a predetermined reaction space for processing the substrate S is provided therein. Of course, the shape of the chamber 100 is not limited to a rectangular cylindrical shape, and may be manufactured in various cylindrical shapes in which an internal space capable of processing the substrate S is provided. The chamber 100 is provided with an opening 110 in communication with the plasma generation module 300. In addition, at one side of the chamber 100, an exhaust unit (not shown) for exhausting the inside of the chamber 100, a substrate entrance (not shown) for entering and exiting the substrate S, and a pressure for adjusting the pressure inside the chamber 100. An adjusting unit (not shown) is provided.

The substrate support module 200 is installed in the chamber 100 to support and horizontally move the substrate S. The substrate support module 200 is connected to a substrate setter 210 on which a wafer S is placed, for example, and a lower portion of the substrate setter 210 to move the substrate setter 210 in a horizontal direction. It comprises a conveying unit 220 to. The substrate mounting portion 210 according to the embodiment is to fix the substrate S by a vacuum suction force, has a circular plate shape, and a heater (not shown) may be embedded therein. The substrate setter 210 is not limited to a means using a vacuum suction force, and various means capable of supporting and fixing the substrate S. For example, an electrostatic chuck supporting the substrate S with an electrostatic force may be used. In addition, the shape of the substrate mounting portion 210 is not limited to the circular shape described above, it may be manufactured in various shapes corresponding to the substrate (S). The transfer unit 220 extends in one direction and is connected to the lower portion of the substrate setter 210. The transfer unit 220 horizontally moves the substrate settling portion 210 mounted on the upper portion thereof in the process progress direction. In this embodiment, the guide rail is used as the transfer unit 220. Of course, the present invention is not limited thereto, and various means capable of horizontally moving the substrate setter 210 may be used as the transfer unit 220.

2 and 3, the plasma generation module 300 according to the first embodiment is disposed on the upper side of the substrate support module 200 outside the chamber 100, and has a dielectric barrier discharge (DBD). ) To discharge the plasma. The plasma generation module 300 is installed to extend in the vertical direction, the electrode is installed in the body 310, the body 310 is grounded and connected to the power supply unit 350 and the electrode 310 in the body 310 A dielectric member 330 is installed to surround the 320.

Body 310 according to the first embodiment is manufactured in a cylindrical shape having an internal space, it is installed to extend in the vertical direction. Of course, the shape of the body 310 is not limited to the cylindrical shape described above, it can be manufactured in various shapes having an internal space. In addition, the body 310 is made of metal, for example, stainless steel (SUS), and is grounded to generate plasma. The upper portion of the body 310 is connected to the raw material supply pipe 500, the raw material supply pipe 500 is a deposition raw material storage (not shown), reactive gas storage (not shown) and purge gas storage (not shown) ) Can be connected. In addition, the lower portion of the body 310 is opened, through which the deposition material, the reaction gas, purge gas, plasma and radicals are injected. Hereinafter, the opening area provided in the lower part of the body will be referred to as the 'jet sphere (312)'.

The electrode 320 extends in the vertical direction in the body 310 and is spaced apart from the inner wall of the body 310. The electrode 320 according to the embodiment is made of a cylindrical shape made of metal, for example, stainless steel (SUS), but is not limited thereto and may be manufactured in various shapes. In addition, the electrode 320 is connected to the power supply unit 350 for supplying power for plasma generation, the power supply unit 350 may supply at least one of RF power and DC power to the electrode 320, Pulse supply is also possible.

The dielectric member 330 is manufactured in a cylindrical shape to surround the outer circumferential surface of the electrode 320, and the outer circumferential surface of the dielectric member 330 is spaced apart from the inner wall of the body 310. Accordingly, the inner circumferential surface of the dielectric member 330 is in contact with the outer circumferential surface of the electrode 320, and the outer circumferential surface of the dielectric member 330 is spaced apart from the inner wall of the body 310. Arc generation between the electrode 320 and the body 310 is suppressed by the dielectric member 330, and plasma is discharged in a space between the body 310 and the dielectric member 330. In the following description, the space between the body 310 and the dielectric member 330 is referred to as a 'plasma generating space 311'. When the plasma is discharged in the plasma generating space 311, a polarization phenomenon is generated in the dielectric member 330 by the plasma, and electric fields and electrons are concentrated on the surface of the dielectric member 330. In this case, since the outer circumferential surface of the dielectric member 330 is exposed to the plasma generation space 311, electric fields and electrons are concentrated on the outer circumferential surface of the dielectric member 330, which causes a large amount of the electric field and the surface of the dielectric member 330. Radicals are produced. As such, by installing the dielectric member 330 between the body 310 and the electrode 320 to generate a high density electric field, high pressure, for example, can generate a stable discharge at atmospheric pressure. In addition, as the electric field is concentrated on the outer circumferential surface of the dielectric member 330, arc generation is lowered as compared with the prior art.

In the plasma generating module 300 according to the embodiment, the separation distance d between the inner wall of the body 310 and the outer circumferential surface of the dielectric member 330 is 1 cm or less, preferably 1 mm to 30 mm, and the width w of the dielectric member 330. ) Should be less than 2cm. In other words, when the width of the dielectric member 330 is expressed in other words, it means a distance from one inner surface of the dielectric member 330 in contact with the electrode 320 to one outer surface of the dielectric member, and the distance is 2 cm or less. Produce to be. This is to facilitate the discharge of the plasma in the space between the body 310 and the dielectric member 330, that is, the plasma space, and to allow the electric field to be easily transferred to the surface of the dielectric member 330. For example, when the separation distance between the body 310 and the dielectric member 330 exceeds 1 cm, the separation distance between the body 310 and the electrode 320 is too large, so that no discharge occurs or the arc ( arc) may occur. In addition, when the width of the dielectric member 330 exceeds 2 cm, the electric field of the dielectric member 330 is hard to be transferred to the surface of the dielectric member 330, so that generation of radicals on the surface of the dielectric member 330 is not easy. You may not. Therefore, in the embodiment, the separation distance between the body 310 and the dielectric member 330 is 1 cm or less, and the width of the dielectric member 330 is 2 cm or less.

The dielectric member 330 according to the embodiment is made of a material having low electrical conductivity, for example, Si, but is not limited thereto, and may be made of various dielectric materials such as AlO ₂ , quartz, or ceramic. In addition, the shape of the dielectric member 330 is not limited to the cylindrical shape described above, and may be manufactured in the shape of various polygons that may surround the outer circumferential surface of the electrode 320.

The plasma generating module 300 according to the first embodiment is manufactured in a cylindrical shape and is installed to extend in the vertical direction. Therefore, the plasma generation module 300 according to the first embodiment is easy to process the circular substrate S or to process the local region of the substrate S. FIG.

4 is a cross-sectional view showing a plasma generating module according to a second embodiment of the present invention. In the following, the content overlapping with the first embodiment will be omitted or briefly described.

4, the plasma generation module 300 according to the second embodiment is disposed extending in the step advancing direction in the width direction preferably, the substrate (S) of the chamber (100), extending in the vertical direction therein, The body 310 having the formed plasma generating space 311 and the pumping spaces 313a and 313b and the dielectric member disposed on one side of the plasma generating space 311 so that one side thereof is exposed to the plasma generating space 311. 330 and the electrode 320 installed to be in contact with the other side of the dielectric member 330, the power supply unit 350 for applying power to the electrode 320, the pumping spaces (313a, 313b) provided in the body 310 It includes a pumping unit (360a, 360b) for pumping. Here, the substrate S may be, for example, a rectangular plate shape.

The body 310 according to the second embodiment is manufactured in the shape of a rectangular flat plate extending in the width direction from the outside of the chamber 100, and preferably made larger than the width of the substrate S. Of course, the shape of the body 310 is not limited to the shape of the rectangle, it can be produced in a flat plate shape of various shapes extending in one direction. An injection hole 312 is provided below the body 310, and the injection hole 312 is disposed under the electrode 320 and the dielectric member 330 and is provided in the plasma generating space 311 and the chamber 100. In communication with 110. In addition, the body 310 is provided with first and second pumping spaces 313a and 313b penetrating the body 310 in the vertical direction, and the first and second pumping spaces 313a and 313b are injection holes 312. It is spaced apart in both directions with respect to). For example, the first pumping space 313a is formed to be spaced apart from the electrode 320 in one direction of the injection hole 312, and the second pumping space 313b is formed in the plasma generating space 311 in the other direction of the injection hole 312. It is formed to be spaced apart from. The upper ends of the first and second pumping spaces 313a and 313b communicate with the first and second pumping units 360a and 360b. Here, each of the first and second pumping units 360a and 360b may include pumping pipes 361a and 361b connected to the first and second pumping spaces 313a and 313b and pumps connected to the pumping pipes 361a and 361b. 362a, 362b).

The dielectric member 330 is installed to extend in the vertical direction in the body 310, one side is exposed to the plasma generating space 311, the other side is installed to contact the electrode 320. Accordingly, the dielectric member 330 is disposed between the electrode 320 and the plasma generating space 311. The dielectric member 330 and the electrode 320 according to the exemplary embodiment may be manufactured in a bar shape having a rectangular cross section. However, the dielectric member 330 and the electrode 320 may be manufactured in various shapes.

Referring to the operation and radical generation process of the plasma generating module 300 according to the second embodiment as follows. When a power source, for example, RF power is supplied to the electrode 320 and deposition materials are supplied to the plasma generating space 311, plasma is discharged to the plasma generating space 311. In this case, since one side of the dielectric member 330 is exposed to the plasma generating space 311, a polarization shape is generated in the dielectric member 330, which causes an electric field and electrons to form on one side of the dielectric member 330. Are concentrated. Accordingly, radicals are generated on one side of the dielectric member 330, and the generated radicals are supplied into the chamber 100 through the injection hole 312 and the opening 110 of the body 310. In this case, the first and second pumping spaces 313a and 313b are pumped by the first and second pumping units 360a and 360b, and the deposition raw material and the reaction gas are discharged to the outside rather than directly under the injection hole 312. And purge gas. Therefore, a deposition raw material, a reaction gas, a purge gas, a plasma, radicals, and the like are injected to the region of the substrate S positioned directly below the injection hole 312 in the region of the substrate S that is horizontally moved, and the reaction is performed. It is not sprayed outward. At this time, as the process is performed while the substrate S is horizontally moved in one direction using the transfer unit 220, the entire surface of the substrate S may be uniformly processed. In the case of the plasma generating module 300 according to the second exemplary embodiment, the plasma generating module 300 may be easily processed in a process of continuously processing the substrate S in one direction or in a process of horizontally moving the substrate S extending in one direction.

5 is a cross-sectional view showing a plasma generating module according to a third embodiment of the present invention. In the following, descriptions overlapping with those of the first and second embodiments will be omitted or briefly described.

Referring to FIG. 5, the plasma generation module 300 according to the third embodiment is installed to extend in the width direction, is installed in the body 310 to be grounded, and is installed to extend up and down in the body 310, and is provided with a power supply unit 350. And a dielectric member 330 installed to surround the outer circumferential surface of the electrode 320 and the electrode 320. In other words, the plasma generating module 300 according to the third embodiment inserts the cylindrical electrode 320 and the dielectric member 330 into the plate-shaped body 310. Here, the inner circumferential surface of the dielectric member 330 is in contact with the outer circumferential surface of the electrode 320, and the outer circumferential surface of the dielectric member 330 is provided to be spaced apart from the inner wall of the body 310. In addition, an injection hole 312 is provided below the body 310 of the plasma generation module 300 so as to communicate with the plasma generation space 311, and the first and second pumping spaces 313a are provided at both sides of the injection hole 312. , 313b) is formed. As described above, the first and second pumping spaces 313a and 313b are formed to penetrate the body 310 in the vertical direction, and are formed in one and the other directions of the plasma generating space 311 and the injection hole 312, respectively. do.

In the above description, the plasma generating module 300 is installed outside the chamber 100, but the present invention is not limited thereto, and the plasma generating module 300 may be installed in the chamber 100.

Hereinafter, a substrate processing method using a substrate processing apparatus including a plasma generating module according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 3.

First, a substrate S, for example, a circular wafer is introduced into the chamber 100, and the substrate S is placed on the substrate setter 210. Subsequently, power is applied to the electrode 320 using the power supply unit 350, the raw materials are supplied to the plasma generating space 311 in the body 310 through the raw material supply pipe 500, and the substrate S is processed. Carry out the process. The interior of the plasma generation module 300 and the interior of the chamber 100 are at atmospheric pressure and supply, for example, 13.56 MHz RF power to the electrodes. In the embodiment, for example, an SiO ₂ thin film is formed on the substrate S by an atomic layer deposition method. To this end, the deposition raw material SiH ₄ is injected into the plasma generating space 311, and a gas, for example, Ar, is injected to generate the plasma. At this time, Ar plasma discharge in the form of glow discharge is performed in the plasma generation space 311, and radicals are generated on the outer circumferential surface of the dielectric member 330. At this time, the body 310 and the electrode 320 are not directly contacted by the dielectric member 330, and as the electric field is concentrated on the outer circumferential surface of the dielectric member 330, between the electrode 320 and the body 310. Arc generation is suppressed. In addition, the dielectric member 330 can generate a high-density electric field, thereby generating stable glow discharge even at atmospheric pressure. SiH ₄ is a dissociated by the Ar plasma is Si _x is generated, wherein the Si _x is injected through the injection hole is adsorbed on the substrate (S). In addition, radicals generated on the outer circumferential surface of the dielectric member 330 are also injected through the injection holes. Thereafter, a purge gas is supplied to the plasma generating space 311 to purge deposition raw materials and reaction by-products which are not adsorbed on the substrate S. Subsequently, when O ₂ is supplied to the plasma generation space 311, radicals generated on the outer circumferential surface of the dielectric member 330 excite O ₂ to generate O radicals, and the Si radicals are adsorbed onto the substrate S. Reacts with _x to form a SiO ₂ thin film. Subsequently, a purge gas is supplied to the plasma generation space 311 to purge the deposition raw material, the reaction gas, and the reaction by-products that did not participate in the reaction that did not react. When the cycle of the adsorption-purge-reaction-purge process is repeated a plurality of times, an SiO 2 thin film having a predetermined thickness is formed on the substrate S. FIG. During the deposition process, the substrate S and the substrate setter 210 may be horizontally moved in one direction by the transfer unit 220. As a result, SiO ₂ thin films are sequentially formed in the region of the substrate S moving under the injection hole 312 of the plasma generation module 300.

Hereinafter, a method of processing a substrate using a substrate processing apparatus according to a second embodiment of the present invention will be described with reference to FIG. 4. In this case, the content overlapping with the first embodiment will be omitted or briefly described.

When the substrate S is seated on the substrate mounting portion 210, power is supplied to the electrode 320 of the plasma generating module 300 having a flat plate shape, and gas for plasma generation is supplied to the plasma generating space 311. do. In addition, it is repeatedly supplied in the order of deposition raw material-purge gas-reactive gas-purge gas, and sprayed toward the substrate S. FIG. Accordingly, the Ar plasma is discharged in the plasma generating space, and electric fields and electrons are concentrated on one side of the dielectric member 330 exposed by the Ar plasma to the plasma generating space 311, thereby generating radicals. At this time, as described above, as the electric field is concentrated on the outer circumferential surface of the dielectric member 330, arcing between the electrode 320 and the body 310 is suppressed. In addition, the dielectric member 330 can generate a high-density electric field, thereby generating stable glow discharge even at atmospheric pressure. Ar plasma, radicals, deposition materials, purge gases, reaction gases, etc. generated in the plasma generating space 311 are injected through the injection holes 312. At this time, the plasma, radicals, deposition raw materials, reactant gases, purge gases, etc. discharged to the outside, not directly below the injection hole 312 are sucked through the first and second pumping spaces 313a and 313b and discharged to the outside. Therefore, plasma, radicals, deposition materials, reactant gases, purge gases, and the like are injected to the region of the substrate S positioned directly below the injection hole 312 in the region of the substrate S that is horizontally moved, and the reaction is performed. It is not sprayed outward. As a result, linear uniformity of Ar plasma, radicals, deposition raw materials, purge gas, and reactant gas sprayed onto the substrate S by the plate-shaped body 310 is improved as compared with the related art. In addition, during the deposition process, the substrate S and the substrate setter 210 move horizontally in one direction by the transfer unit 220. Accordingly, a SiO ₂ thin film having a uniform thickness may be formed on the entire upper surface of the substrate S.

Hereinafter, a method of processing a substrate using a substrate processing apparatus according to a third embodiment of the present invention will be described with reference to FIG. 5. In this case, the content overlapping with the first and second embodiments will be omitted or briefly described.

When power is supplied to the electrode 320 and a gas for generating plasma, such as Ar, is supplied to the plasma generating space 311, an Ar plasma is generated in the plasma generating space arranged to surround the outer circumferential surface of the dielectric member 330. . At this time, radicals are generated on the outer circumferential surface of the dielectric member 330. Arc generation is suppressed by the dielectric member 330, and a high density electric field can be generated, so that stable glow discharge can be generated even at atmospheric pressure. In addition, when the raw materials for the deposition process are supplied to the plasma generating space, the Ar plasma, radicals, and raw materials are injected through the injection holes. At this time, the body according to the third embodiment is manufactured in a flat plate shape, the plasma discharged to the outside of the injection hole 312, the deposition material, the reaction gas and the purge gas, etc., the first and second pumping space (313a, 313b) Is sucked through and discharged to the outside. Therefore, linear uniformity of Ar plasma, radicals, vapor deposition raw materials, purge gas, reaction gas, etc. sprayed onto the substrate S is improved as compared with the related art.

In the above, the thin film was formed on the substrate by using the plasma generation module 300 according to the first to third embodiments. However, the present invention is not limited thereto, and may be applied to various processing processes such as, for example, etching and cleaning.

300: plasma generation module 310: body
320: electrode 330: dielectric member

Claims (11)

A chamber having an internal space;
A substrate setter disposed in the chamber and in which a substrate is placed; And
A plasma generation module supported and fixed to the chamber so as to face the substrate settled portion, and generating plasma therein;
The plasma generation module is provided with an internal space, the body is grounded;
An electrode installed in an inner space of the body; And
In the body, it is installed so as to surround the outer circumferential surface of the electrode, the inner circumferential surface includes a dielectric member in contact with the outer circumferential surface, the outer circumferential surface is spaced apart from the inner wall of the body,
And a separation space between the body and the dielectric member is a plasma generation space in which plasma is generated. The method according to claim 1,
The body is formed extending in the vertical direction,
And the electrode is spaced apart from an inner wall of a body surrounding the plasma generating space in the plasma generating space. The method according to claim 2,
And a spray hole communicating with the plasma generating space at one end of the body. The method according to claim 1,
The body is formed extending in the width direction,
And the electrode is spaced apart from an inner wall of a body surrounding the plasma generating space in the plasma generating space. delete The method according to claim 1,
The body is formed extending in the width direction,
The electrode is installed to be spaced apart from the plasma generating space in the body,
The dielectric member is disposed between the plasma generating space and the electrode, one side is exposed to the plasma generating space, the other side is in contact with the electrode. The method according to claim 4 or 6,
An injection hole is provided in the body to communicate with the plasma generating space,
A pumping space penetrating the body in the vertical direction is provided,
And the pumping space is spaced apart from at least one side of the electrode and the dielectric member. delete The method according to any one of claims 2, 4 and 6,
And a plasma processing space extending in the vertical direction.
delete delete

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