KR20160107147A - Antenna for inductively coupled plasma processing apparatus - Google Patents

Abstract

The present invention provides an inductively connected plasma processing device capable of forming even plasma density. The inductively connected plasma processing device includes multiple wiring groups comprising a first antenna plate (15) and a second antenna plate (16) which are diverged after connected to a power feed member (17b) at one end and arranged to be parallel with each other, wherein the first antenna plate (15) and the second antenna plate (16) are earthed by being collated at the other end. The first antenna plate (15) includes: an inner antenna plate (15a) connected to the power feed member (17b) at one end; an outer antenna plate (15b) earthed at the other end; and a variable capacitor (15c) installed between the inner antenna plate (15a) and the outer antenna plate (15b). Therefore, a large plasma processing device can form even plasma by the variable capacitor (15c) installed between the inner antenna plate (15a) and the outer antenna plate (15b).

Description

An antenna for an inductively coupled plasma processing apparatus (antenna for inductively coupled plasma processing apparatus)

TECHNICAL FIELD [0001] The present invention relates to an antenna of an inductively coupled plasma processing apparatus for performing a process such as etching on a substrate.

2. Description of the Related Art In a manufacturing process of a liquid crystal display (LCD), an OLED and the like, various plasma processing apparatuses such as a plasma etching apparatus and a plasma CVD film forming apparatus are used to perform predetermined processing on a substrate. Conventionally, a capacitively coupled plasma processing apparatus has been used as such a plasma processing apparatus, but recently, an inductively coupled plasma (ICP) processing apparatus having a great advantage of obtaining a high density plasma at a high vacuum has attracted attention.

An inductively coupled plasma processing apparatus includes an RF antenna disposed on an outer side of a dielectric window of a main body container accommodating a substrate to be processed and supplying RF power to the RF antenna while supplying a processing gas into the main body container, A plasma is generated, and a predetermined plasma process is performed on the substrate to be processed by the inductively coupled plasma. As the RF antenna of the inductively coupled plasma processing apparatus, a spiral-shaped flat antenna is widely used.

However, in recent years, the size of the substrate has increased, and the inductively-coupled plasma processing apparatus has also become larger, and accordingly, the RF antenna is also becoming larger.

However, if the spiral-shaped RF antenna is enlarged in this state, the antenna length becomes long and the antenna impedance becomes high, so that matching of the RF power supplied to the RF antenna becomes difficult, and the antenna potential becomes high. When the antenna potential becomes high, capacitive coupling between the RF antenna and the plasma becomes strong, so that the inductively coupled plasma can not be effectively formed, and the electric field distribution is varied, resulting in nonuniform plasma density, do.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an antenna of an inductively coupled plasma processing apparatus capable of uniformly forming a plasma density.

In order to solve the above problems, the present invention provides a plasma processing apparatus including a main body container for receiving a substrate to be processed and subjecting the substrate to plasma processing, a substrate mounting unit for mounting a substrate to be processed in the main body container, A processing gas supply system 12 for supplying a processing gas into the main body vessel 10; an exhaust system 13 for exhausting the inside of the main body vessel 10; A dielectric wall 14 constituting an upper wall and a portion corresponding to the dielectric wall 14 outside the main body container 10 and forming an induction electric field in the main body container 10 by supplying RF power And a power feeding member 17b for supplying RF power to the RF antenna 40. The RF power is supplied to the RF antenna 40 so that the RF power is supplied to the main body container 10 An inductively coupled plasma (plasma) is formed on the substrate S to form a coupled plasma, And a first antenna plate (15) and a second antenna plate (16) branched at one end and connected to the power supply member (17b) The first antenna plate 15 includes an inner antenna plate 15a connected to the power supply member 17b at one end and an outer antenna plate 15b grounded at the other end, And a variable capacitor (15c) provided between the inner antenna plate (15a) and the outer antenna plate (15b).

The plasma can be uniformly formed by controlling the variable capacitor 15c including the variable capacitor 15c provided between the inner antenna plate 15a and the outer antenna plate 15b.

The power supply member 17b is electrically connected to the dielectric wall 14 and the power supply member 17b. The power supply member 17b is connected to the power supply member 17b, To the center of each side from the center of the four wiring groups, and then to each of the four wiring groups.

With this configuration, it is possible to provide an optimal antenna structure for processing the rectangular target substrate S.

The first antenna plate 15 and the second antenna plate 16 have a first bent portion 90 ° at an angle of 90 ° with respect to the power feeding member 17b and a second bent portion at an angle of 90 ° with the first bent portion. A third bend at an angle of 270 ° with the second bend, a fourth bend at an angle of 270 ° with the third bend, and a fifth bend at an angle of 90 ° with the fourth bend. can do.

With this configuration, it is possible to form a uniform plasma in processing the rectangular target substrate S.

The dielectric wall 14 has a circular planar shape and can be connected to each of the wiring groups.

With this configuration, uniform plasma can be formed even when the shape of the substrate S to be processed is circular.

Each of the plurality of wiring groups may be grounded after being connected to the variable capacitor.

After the variable capacitor is installed as described above, it is possible to form a more uniform plasma by being grounded.

The plurality of wiring groups may be connected to the power supply member 17b and the variable capacitors, respectively, and then connected.

By connecting the variable capacitor to the power supply member 17b as described above, more uniform plasma can be formed.

Each of the plurality of wiring groups may be controlled together with the current of the second antenna plate 16 when the capacitor of the first antenna plate 15 is adjusted.

When the capacitor of the first antenna plate 15 is adjusted as described above, the current of the second antenna plate 16 is also controlled, so that a more uniform plasma can be formed.

The present invention is characterized in that a plurality of wiring groups composed of a first antenna plate and a second antenna plate are provided, and a first antenna plate of each wiring group is connected to an inner antenna plate (15a) and an outer antenna plate (15b) (15c), and by controlling the variable capacitor (15c), the plasma can be uniformly formed.

A variable capacitor 15c provided between the inner antenna plate 15a and the outer antenna plate 15b is provided in the structure of the first antenna plate and the inner antenna plate 15a is fixed by the adjustment of the variable capacitor 15c, And the outer antenna plate 15b can be adjusted to optimize the process conditions for the large inductively coupled plasma processing apparatus.

For example, the voltage applied to the inner antenna plate 15a and the outer antenna plate 15b can be adjusted by adjusting the variable capacitor 15c, so that the plasma density at the central portion and the outer portion in the main body container 10 So that the uniformity of the process can be improved.

1 is a cross-sectional view of an inductively coupled plasma processing apparatus according to an embodiment of the present invention,
Fig. 2 is a plan view showing an example of an antenna installed in the apparatus shown in Fig. 1,
3 is an equivalent circuit diagram of an antenna,
4 is a plan view showing another example of the structure of the antenna when the antenna wall is circular.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. 1 is a cross-sectional view of an inductively coupled plasma processing apparatus according to an embodiment of the present invention.

This device is used for performing a substrate processing process such as etching a metal film, an ITO film, an oxide film, or the like when forming a thin film transistor on an LCD glass substrate in the manufacture of LCDs and OLEDs, for example.

The inductively coupled plasma processing apparatus according to an embodiment of the present invention has a rectangular main body 10 of airtight container made of a conductive material, for example, aluminum whose inner wall surface is anodized.

The main body container 10 is detachably assembled and is grounded.

The main body vessel 10 can be partitioned into the antenna chamber 3 and the treatment chamber 4 by the dielectric wall 14 in the upper and lower portions. At this time, the dielectric wall 14 constitutes the ceiling wall of the treatment chamber 4. [

The dielectric wall 14 is made of ceramics such as Al ₂ O ₃ , quartz or the like.

A shower housing (not shown) for supplying a process gas may be inserted into the lower portion of the dielectric wall 14. [ The shower housing is provided in a shape of a + character and can be structured to support the dielectric wall 14 from below.

Further, the shower housing supporting the dielectric wall 14 may be suspended from the ceiling of the main container 10 by a plurality of suspenders (not shown).

Further, the shower housing is not provided on the ceiling side of the main body container 10 but also on the side surface of the main body container 10, and the installation structure thereof is various.

The shower housing may be composed of an anodized aluminum on the inside so that no conductive material, preferably metal, e.g. contaminants, is generated. (Not shown) extending horizontally is formed in the shower housing, and a plurality of gas discharge holes (not shown) extending downward can communicate with the gas flow path.

On the other hand, a gas supply pipe 12 may be provided at the center of the top surface of the dielectric wall 14 so as to communicate with the gas flow path (not shown). The gas supply pipe 12 is passed from the ceiling of the main container 10 to the outside thereof and is connected to a process gas supply system including a process gas supply source, a valve system, and the like. Therefore, in the plasma treatment, the process gas supplied from the process gas supply system is supplied into the shower housing through the gas supply pipe 12, and is discharged into the process chamber 4 from the gas supply hole on the lower face thereof.

A side wall 3a of the antenna chamber 3 and a side wall supporting shelf 5 of the treatment chamber 4 are provided in the main body container 10 and the dielectric wall 14 is mounted on the supporting rack 5 .

An RF antenna 40 is disposed in the antenna chamber 3 such that the dielectric wall 14 faces the dielectric wall 14. The RF antenna 40 is spaced apart from the dielectric wall 14 by a predetermined distance or less by a spacer (not shown) composed of an insulating member.

One or more power supply members 17b are provided in the antenna chamber 3 for supplying power to the RF antenna 40. An RF power supply 17 is connected to these power supply members 17b via a matching unit 17a. Respectively.

During the plasma processing, an RF power source for forming an induction field, for example, a frequency of 13.56 MHz may be supplied from the RF power source 17 to the RF antenna 40. The induction field is formed in the treatment chamber 4 by the RF antenna 40 supplied with the RF power as described above, and the process gas supplied from the shower housing by the induction field is converted into plasma. The output of the RF power supply 17 at this time is appropriately set to be a value sufficient to generate plasma.

A substrate mounting table 20 for mounting the substrate S is provided on the lower side of the treatment chamber 4 so as to face the RF antenna 40 with the dielectric wall 14 therebetween. The substrate table 20 may be made of a conductive material, for example, aluminum whose surface is anodized. The substrate S mounted on the substrate table 20 can be held by suction on the substrate table 20 by an electrostatic chuck (not shown).

 The side wall 4a of the processing chamber 4 is provided with a loading / unloading port (not shown) for loading / unloading the substrate S and a gate valve (not shown) for opening / closing it.

The RF power source 18 can be connected to the substrate table 20 via the matching unit 18a.

The RF power supply 18 can apply a bias RF power source, for example, an RF power source 18 having a frequency of 6 MHz, to the substrate table 20 during the plasma processing. This bias RF power source 18 effectively introduces the ions in the plasma generated in the processing chamber 4 into the substrate S.

In order to control the temperature of the substrate S, a temperature control mechanism composed of a heating means such as a ceramic heater or a refrigerant flow path, and a temperature sensor are provided in the substrate table 20 Not).

An exhaust device 13 including a vacuum pump or the like is connected to the bottom of the process chamber 4 via an exhaust pipe 31. The process chamber 4 is evacuated by the exhaust device 13, 4) I is set and maintained in a predetermined vacuum atmosphere (for example, 1.33 Pa).

Next, a detailed configuration of the RF antenna 40 will be described.

The RF antenna 40 is provided at a portion corresponding to the dielectric wall 14 outside the main body container 10 and forms an induction field in the main container by being supplied with RF power.

The RF antenna 40 includes a first antenna plate 15 and a second antenna plate 16 which are connected to the power supply member 17b at one end thereof and then branch and are arranged parallel to each other, .

Each of the wiring groups is composed of a first antenna plate 15 and a second antenna plate 16, which are connected to the power supply member 17b at one end thereof and then branched and grounded at the other end.

The first antenna plate 15 and the second antenna plate 16 have a plate shape in which a direction in which the first antenna plate 15 and the second antenna plate 16 are arranged is a longitudinal direction. As shown in FIG. 2, , And the second surface larger than the first surface is preferably arranged parallel to each other.

The first antenna plate 15 and the second antenna plate 16 are oriented such that the first side of the first antenna plate 15 and the second antenna plate 16 face the dielectric wall 14 and the second side larger than the first side are disposed parallel to each other, The first antenna plate 15 and the second antenna plate 16 are formed adjacent to each other in parallel to each other so that sufficient induction plasma can be formed for the substrate processing.

The RF antenna having such a structure may be arranged in various forms as shown in FIGS.

The RF antenna 40 may be arranged in a spiral shape from the center portion of the dielectric wall 14 toward the outside.

The first antenna plate 15 includes an inner antenna plate 15a connected to the power supply member 17b at one end thereof, an outer antenna plate 15b grounded at the other end, and an inner antenna plate 15a, And a variable capacitor 15c provided between the first and second electrodes 15b.

When the first antenna plate 15 includes the variable capacitor 15c between the inner antenna plate 15a and the outer antenna plate 15b as described above, the RF antenna 40 adjusts the variable capacitor 15c. So that the plasma to be formed can be uniformly formed.

The variable capacitor 15c is provided between the inner antenna plate 15a and the outer antenna plate 15b to change the value of the capacitor to optimize the uniform plasma formation.

The variable capacitor 15c is preferably a vacuum variable capacitor.

The RF antennas 40 including a plurality of wiring groups are arranged in various structures such as three or four corresponding to the planar shape of the dielectric walls 14, such as rectangular or circular, in a suitable number.

According to one embodiment, the dielectric wall 14 has a rectangular planar shape, and four wiring groups are provided, so that the wiring group can be grounded at the center of each side of the rectangle.

At this time, the power supply member 17b is divided into four parts from the center of the dielectric wall 14 to the center of each side, and then connected to each of the four wiring groups.

The first antenna plate 15 and the second antenna plate 16 have a first bend portion at an angle of 90 ° with the power supply member 17b, a second bend portion at an angle of 90 ° with the first bend portion, A third bend at an angle of 270 ° with the bend, a fourth bend at an angle of 270 ° with the third bend, and a fifth bend at an angle of 90 ° with the fourth bend.

The first bent portion and the second bent portion are generally located at the central portion of the dielectric wall 14 and the fourth bent portion and the fifth bent portion are located generally at the edge portion of the dielectric wall 14. The third bent portion has a central portion and an edge Connect the parts.

According to another embodiment, the dielectric wall 14 has a circular planar shape and can be connected to each of the wiring groups.

With the above-described configuration, the RF antenna 40 is optimized for uniform plasma formation by changing the capacitor value.

In such a plasma optimization, it is preferable that each of the plurality of wiring groups is further grounded after being further connected to the variable capacitor 19a such as a vacuum variable capacitor.

Also, in such a plasma optimization, it is preferable that a plurality of wiring groups are further connected to a variable capacitor (not shown) such as a vacuum variable capacitor and then connected to the power supply member 17b, respectively.

In such a plasma optimization, it is preferable that each of the plurality of wiring groups is controlled together with the current of the second antenna plate 16 when the capacitor of the first antenna plate 15 is adjusted.

10 ... body container 14 ... dielectric wall
3 ... antenna chamber 4 ... processing chamber
40 ... RF antenna 17 ... high frequency power source
17b ... power supply member 20 ... process gas supply system

Claims (7)

A main body vessel (10) for receiving the target substrate (S) and performing a plasma treatment;
A substrate table 20 on which the target substrate S is mounted in the main container 10,
A processing gas supply system (12) for supplying a processing gas into the main container (10)
An exhaust system (13) for exhausting the inside of the main body container (10)
A dielectric wall 14 constituting an upper wall of the main body container 10,
An RF antenna 40 installed at a portion corresponding to the dielectric wall 14 outside the main body container 10 to form an induction field in the main body container 10 by supplying RF power,
And a power supply member (17b) for supplying RF power to the RF antenna (40)
The inductively coupled plasma processing apparatus according to claim 1, wherein the RF power is supplied to the RF antenna (40) to form an inductively coupled plasma in the main body vessel (10) to perform plasma processing on the substrate (S)
A plurality of wiring groups including a first antenna plate 15 and a second antenna plate 16 which are connected to the power supply member 17b at one end and are branched after being connected to each other and arranged to be parallel to each other and to be grounded at the other end In addition,
The first antenna plate 15 includes an inner antenna plate 15a connected to the power supply member 17b at one end thereof, an outer antenna plate 15b grounded at the other end, And a variable capacitor (15c) installed between the outer antenna plates (15b). The method according to claim 1,
The dielectric wall 14 has a rectangular planar shape, the wiring groups are provided in four, the wiring group is grounded at the center of each side of the rectangular shape,
The power feeding member (17b) is divided into four portions at the center of each side from the center of the dielectric wall (14), and then connected to each of the four wiring groups. 3. The method of claim 2,
The first antenna plate 15 and the second antenna plate 16 have a first bent portion 90 ° at an angle of 90 ° with respect to the power feeding member 17b and a second bent portion at an angle of 90 ° with the first bent portion. A third bend at an angle of 270 ° with the second bend, a fourth bend at an angle of 270 ° with the third bend, and a fifth bend at an angle of 90 ° with the fourth bend. Wherein the antenna is an inductively coupled plasma processing apparatus. The method according to claim 1,
The dielectric wall (14) has a circular planar shape and is connected to each of the wiring groups. The method according to claim 1,
Wherein each of the plurality of wiring groups is grounded after being connected to a variable capacitor. The method according to claim 1,
The plurality of wiring groups are connected to the power supply member (17b) and variable capacitors, respectively, and then connected. The method according to claim 1,
Wherein each of the plurality of wiring groups is controlled together with a current of the second antenna plate (16) when a capacitor of the first antenna plate (15) is adjusted.

Images