KR101489828B1 - Substrate holder module - Google Patents

Abstract

The present invention relates to a substrate support module which includes a ceramic support plate, a conductive edge ring, a support unit, and a metal adapter. The ceramic support plate where a substrate is supported on one surface thereof includes an electrostatic chuck. The conductive edge ring surrounds the outer circumferential surface of the ceramic support plate. The support unit penetrates the bottom unit of a chamber in order to be extended to the inside of the chamber, and supports the ceramic support plate and the conductive edge ring. The metal adapter is placed between the ceramic support plate and the support unit. The ceramic support plate brazed to the metal adapter is detachably coupled to the support unit. Therefore, the substrate support module can reduce damage to the ceramic support plate during a ceramic support plate mounting process and a substrate processing process by coupling the ceramic support plate to the support unit through the metal adapter, can structurally simplify an electrical grounding path around the ceramic support plate by bringing the conductive edge ring in contact with the support unit, and can improve safety and productivity of various processing processes of the substrate.

Description

[0001] Substrate holder module [0002]

The present invention relates to a substrate support module, and more particularly to a substrate support module with improved structure to improve service life.

Semiconductor devices are fabricated by repeating unit processes such as ion implantation, thin film deposition, and heat treatment several times. Among the facilities used in this semiconductor process, the vapor deposition equipment is shown in Fig. Generally, the facility is provided with a chamber 10 for performing a substrate processing process. A substrate S and a target T are provided in the chamber 10 and are arranged to face each other. The target T is mounted on and supported by the chamber lid 12 of the chamber 10 and the substrate S is fixedly supported on a support unit 50 provided in the chamber body 11 of the chamber 10. [ A ceramic disc 20 and a base disc 21 are provided between the support unit 50 and the substrate S. The ceramic disk 20 and the base disk 21 fix the substrate S and adjust the temperature of the substrate S to a desired temperature during the course of the substrate processing. That is, the substrate S is fixedly supported on the upper surface of the ceramic disc 20, and an electrostatic chuck is provided inside the ceramic disc 20 for this purpose. In addition, an edge ring 30 is disposed so as to surround the outer periphery of the ceramic disc 20 in order to electrically ground the periphery of the ceramic disc 20 during the substrate processing process. At this time, the edge ring 30 is held in contact with the upper surface of the base disc 21 made of ceramic. The coupling bolt 40 is mounted through the coupling portion 60 of the base disk 21 and the support unit 50 so as to detachably connect the ceramic disk 20 to the support unit 50. [ The coupling part 60 of the base plate 21 and the supporting unit 50 may be coated with a separate conductive material or a separate conductive ceramic may be used to form the electrical ground path of the edge ring 30, .

In the conventional facility, for example, in Korean Patent Laid-Open No. 10-2004-0030917, ceramics have brittleness in their material, and thus, in the conventional equipment, the base plate 21 is supported through the coupling bolt 40 An impact is applied to the coupling portion 60 when the coupling portion 60 is directly coupled to the unit 50, so that the coupling portion 60 may be damaged. In addition, in the conventional equipment, when the edge ring 30 is contacted with the upper surface of the base disc 21, the impact due to contact with the contact surface is applied, and the contact surface may be damaged. During the substrate processing process, the temperature inside the chamber 10 changes within a desired temperature range. During the temperature change process, the load is repeatedly applied to the coupling portion 60 due to the difference in the amount of thermal expansion between the ceramic and the metal Is applied. As a result, the engaging portion 60 may be fatigued. Of course, a brazing method for bonding ceramic and metal other than the coupling through the above-described coupling bolts 40 has been conventionally proposed. However, since the ceramic support plate 20 is used within the service life for the cleanliness of the substrate S and then periodically exchanged, the ceramic support plate 20 must be detachably coupled to the support unit 50, It is difficult to apply the brazing method to the method of joining the supporting unit 20 and the supporting unit 50. [

Therefore, it is required to overcome the breakage problem that occurs in the coupling portion 60 of the ceramic support plate 20 while facilitating the replacement of the ceramic support plate 20.

KR 10-2004-0030917 A

The present invention provides a substrate support module capable of preventing breakage of a component.

The present invention provides a substrate support module that can improve the service life of the component.

The present invention provides a substrate support module that can simplify the grounding structure of the component and improve the grounding efficiency.

A substrate supporting module according to an embodiment of the present invention includes: a ceramic supporting plate supporting a substrate on one surface; A conductive edge ring disposed to surround an outer circumferential surface of the ceramic support plate; A support unit extending through the bottom of the chamber and extending into the chamber, the support supporting the ceramic support plate and the conductive edge ring; And an annular metal adapter disposed between the ceramic support plate and the support unit; . ≪ / RTI >

The ceramic support plate may include an electrostatic chuck therein.

The ceramic support plate may be brazed to the upper surface of the metal adapter.

The metal adapter may be detachably coupled to the support unit.

The conductive edge ring may be in contact with the support unit.

The ceramic support plate may be spaced apart from the conductive edge ring and the support unit.

A support unit outlet is formed along the edge of the upper end of the support unit at the upper end of the support unit, and the conductive edge ring can be contactably supported on the upper surface of the support unit protrusion.

A support unit recess is formed in the upper end of the support unit, and the metal adapter is inserted into the support unit recess and can be coupled and supported to the bottom surface of the support unit recess.

The metal adapter may be inserted into the recess of the support unit so as to be spaced apart from the inner circumferential surface of the support unit recess.

The support unit may be provided with a bellows connecting the support unit and the chamber to electrically ground the support unit to the chamber.

A sealing member may further be disposed on a mating surface of the metal adapter and the support unit.

According to an embodiment of the present invention, there is provided a substrate support module having an improved coupling structure by using a metal adapter detachably mounting a ceramic support plate to a support unit, from which a ceramic support plate The damage can be suppressed, and the service life of the substrate supporting module can be improved.

Further, according to an embodiment of the present invention, it is possible to connect the conductive edge ring to the support unit and connect the support unit to the chamber to form a path through which the ceramic support plate can be electrically grounded. Thus, the ground path of the finger support module for grounding the conductive edge ring in the chamber can be structurally simplified.

Therefore, stability and productivity of various processing steps of the substrate can be improved.

1 is a schematic view of a conventional substrate processing facility;
2 is a schematic view of a substrate support module and a substrate processing apparatus having the same according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described below, but may be embodied in various forms. It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. The drawings may be exaggerated in size to illustrate the embodiments, and like reference numbers in the drawings indicate like elements.

2 is a schematic view illustrating a substrate supporting module and a substrate processing apparatus having the same according to an embodiment of the present invention.

2, a substrate supporting module 1000 according to an embodiment of the present invention includes a ceramic supporting plate 100 having a substrate S supported on one surface thereof and including an electrostatic chuck (not shown), a ceramic supporting plate A conductive edge ring 200 disposed to surround the outer circumferential surface of the ceramic support plate 100 and the conductive edge ring 200 and extending through the bottom of the chamber 10 to the inside of the chamber 10, And an annular metal adapter 400 disposed between the support unit 300 and the ceramic support plate 100 and the support unit 300 and configured to perform a substrate processing process within the chamber 10 for processing the substrate S, The substrate S is fixed, for example, during the sputtering process, and the temperature of the substrate S is adjusted.

Here, the substrate S may be a wafer constituting a base of a semiconductor device to be processed in a semiconductor processing facility. The chamber 10 forms the body of the facility for processing the substrate S and has an internal space through which the processing of the substrate S can be carried out. The chamber 10 may be manufactured to have a single body or a detachable detachable body. In this embodiment, the chamber body 11 and the chamber lid 12 are detachably mounted The combined chamber 10 is illustrated. The chamber 10 may be provided with vacuum adjusting means (not shown) capable of controlling the inside thereof in a vacuum atmosphere and gas supplying means (not shown) capable of supplying a process gas into the chamber. The chamber 10 may also be provided with a sealing means (not shown) to seal between the chamber body 11 and the chamber lid 12.

When the present embodiment is applied to the sputtering process, a target T is provided in the chamber 10 to supply a raw material for forming a thin film including a metal film, an insulating film, and an oxide film on the substrate S, And a power generating unit (not shown) capable of forming an electric or magnetic field in the chamber 10 may be provided. The target (T) and the substrate (S) are arranged to face each other inside the chamber (10). In this embodiment, the target T is fixed to a target supporting module (not shown) provided on the lower surface of the chamber lid 12, and the substrate S is supported by a substrate supporting module 1000 provided inside the chamber body 11, Respectively. The target T may be fixed to the target supporting module (not shown) in a manner suitable for each process among the target fixing methods including the adhesive force, the electrostatic force and the attraction force.

The substrate S may be fixed to the substrate supporting module 1000 by an electrostatic force or a vacuum attraction force. In this embodiment, a method of fixing the substrate S by an electrostatic force is illustrated. During the substrate processing process, the substrate S may be heated to a high temperature, for example 300 DEG C to 600 DEG C, so that each component of the above-described equipment can be provided with cooling means (not shown) .

The above-described chamber 10 may be applied to a general constituent part and a configuration method applied to a semiconductor processing facility, and the present invention is not limited to a specific configuration in the description of the embodiments of the present invention. Therefore, in order not to obscure the gist of the present invention, a detailed description thereof will be omitted.

Hereinafter, a substrate supporting module 1000 according to an embodiment of the present invention will be described.

The ceramic support plate 100 may be formed in a shape and size corresponding to the shape and size of the substrate S, and in this embodiment, the ceramic support plate 100 is formed into a disc shape having a predetermined diameter. The ceramic support plate 100 serves to support and fix the substrate S placed on the upper surface of the ceramic support plate 100 during the substrate processing process and to control the temperature of the substrate S. [ To this end, the ceramic support plate 100 is provided with an electrostatic chuck (not shown) capable of generating an electrostatic force, and is formed by enclosing an electrostatic chuck with an insulating member such as ceramic to electrically insulate the electrostatic chuck from the outside. When electric power is applied to the electrostatic chuck, an electrostatic force such as a Coulomb force and a Johnson-Labe force is generated in the insulating member located between the substrate S and the electrostatic chuck placed on the upper surface of the ceramic support plate 100, S). The configuration and configuration of the electrostatic chuck (not shown) may be applied to various electrostatic chuck components used in semiconductor processing equipment. Power supply means (not shown) may be connected to the electrostatic chuck. At this time, the power supply means (not shown) may enter the internal space provided in the support unit 300 to be described later and be electrically connected to the electrostatic chuck. On the other hand, in order to compensate the temperature change of the substrate S fixed on the ceramic support plate 100 and to uniformly control the temperature of the substrate S at a desired temperature, for example, 300 DEG C or more, (Not shown) may be further provided.

The conductive edge ring 200 is disposed to surround the outer circumferential surface of the ceramic support plate 100 and the raw material to be deposited on the substrate S during the substrate processing process is transferred to the lower portion of the chamber 10, It can be prevented from being accumulated in the supporting unit 300, which is a supporting member. The conductive edge ring 200 serves to electrically ground the vicinity of the outer circumferential surface of the ceramic support plate 100 during the process of processing the substrate S. At this time, the conductive edge ring 200 is in contact with the support unit 300, and the support unit 300 is connected to the chamber 10 so that an electrical ground path can be formed. Here, the conductive edge ring 200 is contactably connected to the support unit 300 so that the conductive edge ring 200 is supported by the support unit 300 (not shown) without mechanical or chemical coupling between the conductive edge ring 200 and the support unit 300 And each of the contact surfaces maintains a contact state. That is, in the substrate supporting module 1000 according to the present embodiment, the conductive edge ring 200 does not necessarily need to be coupled to the supporting unit 300 but is connected to the supporting unit 300 to electrically connect the supporting unit 300 to the supporting unit 300 And grounded. Thus, the conductive edge ring 200 can be easily installed.

Meanwhile, the conductive edge ring 200 may be made of a conductive material such as a metal material so as to have a desired electrical conductivity, and the shape thereof may be formed in an annular shape corresponding to the shape of the ceramic support plate 100. In this embodiment, an annular conductive edge ring 200 is illustrated in which the inner diameter is formed larger than the diameter of the ceramic support plate 100 and the outer diameter of the annular conductive edge ring is formed to be larger than the outer diameter of the support unit upper end 320 described later. At this time, a groove having a predetermined depth may be formed on the upper surface of the conductive edge ring 200 along the circumference of the edge ring 200.

The support unit 300 extends into the chamber 10 through the bottom of the chamber 10 and supports the ceramic support plate 100 and the conductive edge ring 200. To this end, the support unit 300 includes a support unit body 310 extending in the longitudinal direction and arranged to penetrate the bottom of the chamber 10 in the up-and-down direction, and a support unit body 310 located inside the chamber 10, And a support unit upper part 320 formed at an end of the support 310 in a direction intersecting the longitudinal direction of the support unit body 310 to form an electrical ground path with the conductive edge ring 200 It may be made of a conductive material such as a metal material. The support unit 300 also includes a support unit 300 that prevents the chamber 10 from being hermetically sealed by the support unit 300 and electrically grounds the support unit 300 to the chamber 10. [ And a bellows for connecting the chamber 10 with the bellows.

The support unit body 310 may be formed in a tubular shape having an inner space opened in a vertical direction. At least a part of the support unit body 310 is disposed at a lower portion inside the chamber 10 to support and support the support unit upper end 320. The bellows 330 is spaced from the outer circumferential surface of the support unit body 310 so as to surround the outer circumferential surface of the support unit body 310. The upper end of the bellows 330 is coupled to the lower surface of the support unit upper end 320, Is coupled to the inner lower surface of the chamber 10. The upper and lower ends of the bellows 330 and the lower surface of the upper portion 320 of the supporting unit and the lower surface of the inner side of the chamber 10 are connected to each other so as to seal the inside of the chamber 10 from the inside of the bellows 330. [ Sealing means (not shown) may be provided on each contact surface.

The support unit upper end 320 is formed at the end of the support unit body 310. The support unit upper part 320 serves to support the ceramic support plate 100 and the conductive edge ring 200 described above inside the chamber 10. [ For this purpose, in this embodiment, a support unit upper end 320 having a shape and size corresponding to the shape and size of the ceramic support plate 100, for example, a circular support unit upper end 320 having a larger diameter than the ceramic support plate 100, . At this time, a support unit protrusion 321 and a support unit recess 322 are formed on the upper surface of the support unit upper part 320, and the upper surface of the support unit upper part 320 is bent downward toward the center position of the upper surface . In addition, the support unit upper end portion 320 is formed so as to penetrate in the vertical direction in the horizontal direction so that the support unit body portion 310 and the inside thereof communicate with each other, and a space is provided inside the support unit 300. Power supply means (not shown) and heating means (not shown) may be inserted into the support unit 300 and connected to the ceramic support plate 100 through the space provided.

Hereinafter, the support unit protrusion 321 and the support unit recess 322 will be described.

The support unit protrusion 321 is formed along the edge of the support unit upper end 320 at the support unit upper end 320 and the conductive edge ring 200 can be contactably supported on the upper surface of the support unit protrusion 321 formed . Meanwhile, conventionally, as shown in Fig. 1, the edge ring 30 is directly contacted with the base disc 21 formed of ceramic. Conventionally, a conductive material is coated on at least a part of the base disc 21 contacting the edge ring 30 to form an electrical ground path of the edge ring 30, Separate means were provided. In this embodiment, because the conductive edge ring 200 is held in direct contact with the support unit protrusion 321, the support unit protrusion 321 forms an electrical ground path to the conductive edge ring 200, The configuration of the facility can be simplified. In addition, in the related art, when the edge ring 30 is installed, the impact applied to the base plate 21 by the edge ring 30 is accumulated, and the base plate 21 is cracked. In this embodiment, the conductive edge ring 200 is held in contact with the support unit protrusion 321 which is stronger than the ceramic material, so that the problem of equipment damage due to breakage of the conventional base plate can be prevented. At this time, the conductive edge ring 200 is held on the upper surface of the support unit protrusion 321 without being necessarily connected to the support unit protrusion 321. [

A support unit recess 322 is formed in the support unit upper end 320 so as to be spaced from the edge of the support unit upper end 320. The metal adapter 400 is inserted into the support unit recess 322, And can be coupled and supported on the bottom surface of the portion 322. That is, the support unit recess 322 serves to provide the support unit upper end 320 with a predetermined space into which the metal adapter 400 is inserted. At this time, the metal adapter 400 is inserted into the support unit recess 322 so as to be spaced apart from the inner peripheral surface of the support unit recess 322. The contact area between the support unit 300 and the metal adapter 400 is limited to the lower surface of the metal adapter 400 and the ceramic support plate 100 is connected to the support unit 300 through the metal adapter 400 The loss of heat can be suppressed. During the substrate processing process, an atmosphere temperature of, for example, 300 to 600 DEG C is formed in the chamber 10 at a high temperature, and the temperature gradually changes under the control of the process system. This temperature change allows the metal adapter 400 to thermally expand during the substrate processing process. At this time, as the metal adapter 400 is spaced from the inner circumferential surface of the support unit recess 322, a space that can accommodate the thermal expansion of the metal adapter 400 is provided, thereby preventing structural damage caused by thermal expansion.

Hereinafter, a metal adapter 400 for detachably coupling the ceramic support plate 100 to the support unit 300 will be described.

The metal adapter 400 is disposed between the ceramic support plate 100 and the support unit 300 and may be formed into an annular shape corresponding to the shape of the ceramic support plate 100 and the support unit recess 322 have. Thus, the contact surface between the ceramic disc 100 and the support unit 300 and the metal adapter 400 can be reduced compared with the case where the metal adapter 400 is formed to have a disc shape. This makes it possible to more effectively suppress the loss of heat from the ceramic disc 100 to the support unit 300 through the metal adapter 400. The outer diameter of the metal adapter 400 may be smaller than the diameter of the support unit recess 322 so that the metal adapter 400 is spaced from the inner circumferential surface of the support unit recess 322 as described above. The metal adapter 400 is formed such that the ceramic support plate 100 coupled to the upper surface of the metal adapter 400 is spaced apart from the support unit 300, May be formed to be larger than the formation depth of the recess 322. The ceramic support plate 100 coupled to the support unit 300 through the metal adapter 400 is separated from the support unit 300 and supported by the ceramic support plate 100 from the ceramic support plate 100. [ It is possible to prevent heat from being lost to the unit 300. In addition, the ceramic support plate 100 may be thermally expanded by the process temperature in the chamber 10 during the substrate processing process. Since the ceramic support plate 100 is spaced apart from the support unit 300 by a predetermined distance, a space that can accommodate the thermal expansion of the ceramic support plate 100 is provided. Thus, the ceramic support plate 100 is structurally Damage can be prevented.

Hereinafter, the coupling relationship between the ceramic support plate 100, the metal adapter 400, and the support unit 300 will be described.

As described above, the metal adapter 400 serves to detachably mount the ceramic support plate 100 to the support unit 300. To this end, the ceramic support plate 100 is brazed to the upper surface of the metal adapter 400, and the metal adapter 400 is detachably coupled to the support unit 300. That is, conventionally, a base plate 21 formed of ceramic is directly bolted to a support unit 50 formed of a metal. Alternatively, in this embodiment, a metal adapter 400 is provided between the ceramic support plate 100 and the support unit 300, the support unit 300 and the metal adapter 400 are detachably coupled by, for example, The metal adapter 400 and the ceramic support plate 100 are coupled by brazing to form the substrate supporting module 1000. Therefore, damage due to the structural weakness of the coupling portion due to the conventional bolting can be prevented by using the metal adapter 400 according to the present embodiment. Hereinafter, the coupling member 410 will be described in detail. In this embodiment, a brazing layer is formed between the ceramic support plate 100 and the metal adapter 400 by brazing between the ceramic support plate 100 and the metal adapter 400. The heat dissipation from the ceramic support plate 100 to the metal adapter 400 can be suppressed by the formed brazed bond layer.

A coupling member 410 may be provided between the metal adapter 400 and the support unit 300 so as to detachably connect the metal adapter 400 to the support unit 300. Various members capable of mechanically coupling the metal adapter 400 to the support unit 300 can be applied to the engagement member 410. In this embodiment, the metal adapter 400 is bolted to the support unit 300 (E.g., a bolt). Conventionally, the ceramic support plate 20 is coupled to the support unit 50 via a base plate 21 provided on the lower surface of the ceramic support plate 21. Specifically, the base disc 21 made of ceramic is directly bonded to the supporting unit 50 through the engaging member 40, for example, a bolt. Generally, ceramic materials are brittle, and when subjected to the same impact, cracks tend to occur as compared with metal materials. Conventionally, when the base disk 21 and the support unit 50 are coupled, the impact applied to the coupling portion of the base disk 21 and the impact due to the thermal expansion of the base disk 21 accumulate, The operating life of the ceramic supporting plate 20, for example, before the operating life of the ceramic supporting plate 20, is broken. As a result, there has been a problem of damage to facilities and increase in maintenance cost. In order to prevent such a problem, the conventional method of directly connecting the base plate 21 and the support unit 50 is improved. In this embodiment, the ceramic support plate 100 is supported by the support unit 300 via the metal adapter 400 . Accordingly, it is possible to reduce the number of times of replacing parts of the equipment, for example, the number of times of replacement of the ceramic support plate, and reduce the operating cost accordingly.

A sealing member 420 such as an O-ring made of an elastic rubber material or an O-ring made of a metal may be disposed on the coupling surface of the metal adapter 400 and the support unit 300. The inside of the chamber 10 can be sealed from the inside of the supporting unit 300 by the sealing member 420 to keep the inside of the chamber 10 airtight.

The metal adapter 400 may include a metal material having a coefficient of thermal expansion corresponding to the coefficient of thermal expansion of the ceramic. In this embodiment, the metal adapter 400 may include molybdenum (Mo) or kovar (400). Of course, the material to be applied to the metal adapter 400 is not particularly limited to these materials.

The substrate supporting module 1000 according to the present embodiment thus formed detachably couples the ceramic supporting plate 100 to the supporting unit 300 through the metal adapter 400 so that the ceramic supporting plate 100, It is possible to extend the service life of the apparatus and reduce the operation cost. The conductive grounding ring 200 is contacted with the support unit 300 to easily form the electrical ground path of the periphery of the substrate S fixed by the ceramic support plate 100 and the ceramic support plate 100 can do.

Although the above embodiment of the present invention is applied to a sputtering facility, the present invention can be applied to various facilities for performing various substrate processing processes. It should be noted that the above-described embodiments of the present invention are for explanation purposes only and are not for the purpose of limitation. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

100: ceramic support plate 200: conductive edge ring
300: support unit 321: support unit protrusion
322: support unit recess 400: metal adapter
410:

Claims (11)

A ceramic support plate for supporting the substrate on one surface thereof;
A conductive edge ring disposed to surround an outer circumferential surface of the ceramic support plate;
A support unit extending through the bottom of the chamber and extending into the chamber, the support supporting the ceramic support plate and the conductive edge ring; And
And an annular metal adapter disposed between the ceramic support plate and the support unit,
A supporting unit protrusion is formed at an upper end of the supporting unit along the edge of the upper end of the supporting unit,
Wherein the conductive edge ring is in contact with the upper surface of the support unit protrusion.
The method according to claim 1,
Wherein the ceramic support plate includes an electrostatic chuck therein.
The method according to claim 1,
Wherein the ceramic support plate is brazed to an upper surface of the metal adapter,
The method according to claim 1,
And the metal adapter is detachably coupled to the support unit.
delete The method according to claim 1,
Wherein the ceramic support plate is spaced from the conductive edge ring and the support unit.
delete The method according to claim 1,
A support unit recess is formed in the upper end of the support unit,
Wherein the metal adapter is inserted into the support unit recess and is coupled to the bottom surface of the support unit recess.
The method of claim 8,
Wherein the metal adapter is inserted into the recess of the support unit so as to be spaced apart from the inner circumferential surface of the support unit recess.
The method according to claim 1,
Wherein the support unit is provided with a bellows connecting the support unit and the chamber to electrically ground the support unit to the chamber.
The method of claim 4,
Wherein a sealing member is further disposed on a mating surface of the metal adapter and the support unit.

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