KR20160002535A - Substrate treating apparatus - Google Patents

Abstract

The present invention relates to a substrate processing apparatus. The substrate processing apparatus according to an embodiment of the present invention comprises: a process chamber; a substrate support unit; an antenna; and a dielectric plate. The dielectric plate has a base plate and a lower plate which can be attached to and detached from the bottom of the base plate. Accordingly, the lower plate is provided with a material having higher resistance to plasma than that of the base plate, thereby preventing the dielectric plate from being damaged by plasma. Only a part of the dielectric plate can be replaced, thereby achieving easy replacement and reducing costs required for the replacement. The lower plate is provided with a thickness thinner than that of the base plate, thus transmissivity and a refractive index of a microwave electric field for the entire dielectric plate do not deviate from the scope of process requirement even when the lower plate is provided with a material that is different from that of the base plate. In addition, by changing the shape of the lower plate and the shape of a face where the base plate and the lower plate are in contact with each other, the density of each area of the microwave electric field can be adjusted.

Description

[0001] SUBSTRATE TREATING APPARATUS [0002]

The present invention relates to a substrate processing apparatus, and more particularly, to an apparatus for processing a substrate using plasma.

Plasma is an ionized gas state produced by very high temperature, strong electric field or RF electromagnetic fields, and composed of ions, electrons, radicals, and so on. In the semiconductor device manufacturing process, various processes are performed using plasma. For example, the etching process is performed by colliding the ion particles contained in the plasma with the substrate.

When a plasma is generated using microwaves, the microwaves are radiated into the process chamber through the dielectric plate. 1 is a sectional view showing a general substrate processing apparatus. Referring to Fig. 1, generally, the dielectric plate 1 is provided as an integral type, the entirety of which is made of the same material. Therefore, when the dielectric plate 1 is damaged, the replacement is not easy and the replacement cost is high. In addition, in order to prevent the damage of the dielectric plate due to the plasma, it is difficult to satisfy the projection and the refractive index of the microwave when changing the material of the dielectric plate as a material having a strong plasma resistance. In general, the microwave electric field density is controlled by the shape and arrangement of slots of the antenna, but it is not easy to control the microwave electric field density.

The present invention is to provide a substrate processing apparatus that prevents damage to a dielectric plate due to plasma.

It is still another object of the present invention to provide a substrate processing apparatus capable of reducing a dielectric plate replacement cost.

The present invention also provides a substrate processing apparatus capable of adjusting the electric field density of each microwave region.

The problems to be solved by the present invention are not limited thereto, and other matters not mentioned can be clearly understood by those skilled in the art from the following description.

The present invention provides a substrate processing apparatus. According to one embodiment, the substrate processing apparatus includes a processing chamber having a space formed therein; A substrate support unit for supporting the substrate in the process chamber; An antenna disposed on the substrate supporting unit and having a plurality of slots; A microwave applying unit for applying a microwave to the antenna; And a dielectric plate provided under the antenna and diffusing and transmitting microwaves into the space inside the process chamber, wherein the dielectric plate comprises: a base plate provided with a dielectric material; And a lower plate coupled to a bottom surface of the base plate.

A groove is formed in the bottom surface of the base plate, and the bottom plate is inserted into the groove.

The thickness of the bottom plate is not more than 30% of the thickness of the base plate.

The distance between the base plate and the bottom plate may be different depending on the region.

The bottom plate may be provided with a different thickness for each region.

A portion of the upper surface of the lower plate may protrude upward relative to other regions.

The base plate and the bottom plate may be provided in different materials.

The lower plate may be provided with a material having a higher plasma resistance than the base plate.

The lower plate may be provided to be detachable and attachable to one of the upper surface of the lower plate or the lower surface of the base plate and the other may have a fitting groove into which the fitting protrusion can be inserted.

The lower plate may be made of a material including ceramics, a material including aluminum nitride (AlN), or a material including quartz.

The substrate processing apparatus according to the embodiment of the present invention can prevent the damage of the dielectric plate due to the plasma.

Further, the substrate processing apparatus according to the embodiment of the present invention can reduce the replacement cost of the dielectric plate.

In addition, the substrate processing apparatus according to the embodiment of the present invention can control the field density of each microwave region.

1 is a sectional view showing a general substrate processing apparatus.
2 is a cross-sectional view illustrating a substrate processing apparatus according to an embodiment of the present invention.
3 is a bottom view showing the bottom of the antenna of Fig.
Fig. 4 is a bottom view of the base plate of Fig. 2; Fig.
5 is a perspective view showing the bottom plate of Fig.
6 and 7 are cross-sectional views showing one embodiment of the dielectric plate of FIG.

Hereinafter, 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 following embodiments. This embodiment is provided to more fully describe the present invention to those skilled in the art. Thus, the shape of the elements in the figures has been exaggerated to emphasize a clearer description.

2 is a sectional view showing a substrate processing apparatus 10 according to an embodiment of the present invention.

Referring to FIG. 2, the substrate processing apparatus 10 performs plasma processing on the substrate W. As shown in FIG. The substrate processing apparatus 10 includes a process chamber 100, a substrate support unit 200, a gas supply unit 300, a microwave application unit 400, an antenna 500, a chopper plate 600, .

The process chamber 100 is formed with a space 101 therein and the internal space 101 is provided with a space in which the substrate W processing process is performed. The process chamber 100 includes a body 110 and a cover 120. The upper surface of the body 110 is opened and a space is formed therein. The cover 120 is placed on top of the body 110 and seals the open top surface of the body 110. The cover 120 is stepped inside the lower end so that the upper space has a larger radius than the lower space.

An opening (not shown) may be formed in one side wall of the process chamber 100. The opening is provided as a passage through which the substrate W can enter and exit the process chamber 100. The opening is opened and closed by a door (not shown).

An exhaust hole 102 is formed in the bottom surface of the process chamber 100. The exhaust hole 102 is connected to the exhaust line 131. With the exhaust through the barrier line 131, the interior of the process chamber 100 can be maintained at a pressure lower than normal pressure. The reaction byproducts generated in the process and the gas remaining in the process chamber 100 may be discharged to the outside through the exhaust line 131.

The substrate support unit 200 is located inside the process chamber 100 and supports the substrate W. The substrate support unit 200 includes a support plate 210, a lift pin (not shown), a heater 220, and a support shaft 230.

The support plate 210 has a predetermined thickness and is provided as a disk having a larger radius than the substrate W. [ The substrate W is placed on the upper surface of the support plate 210. According to the embodiment, the support plate 210 is not provided with a structure for fixing the substrate W, and the substrate W is provided to the process while being placed on the upper surface of the support plate 210. Alternatively, the support plate 210 may be provided as an electrostatic chuck for fixing the substrate W using electrostatic force, or may be provided as a chuck for fixing the substrate W in a mechanical clamping manner.

A plurality of lift pins are provided and located in each of the pin holes (not shown) formed in the support plate 210. The lift pins move up and down along the pin holes to load the substrate W onto the support plate 210 or unload the substrate W placed on the support plate 210. [

The heater 220 is provided inside the support plate 210. The heater 220 is provided as a helical coil and can be embedded in the support plate 210 at uniform intervals. The heater 220 is connected to an external power source (not shown) and generates heat by resistance to a current applied from an external power source. The generated heat is transferred to the substrate W via the support plate 210, and the substrate W is heated to a predetermined temperature.

The support shaft 230 is positioned below the support plate 210 and supports the support plate 210.

The gas supply unit 300 supplies the process gas into the process chamber 100. The gas supply unit 300 may supply the process gas into the process chamber 100 through the gas supply hole 105 formed in the side wall of the process chamber 100.

The microwave applying unit 400 applies a microwave to the antenna 500. The microwave application unit 400 includes a microwave generator 410, a first waveguide 420, a second waveguide 430, a phase shifter 440, and a matching network 450.

The microwave generator 410 generates a microwave.

The first waveguide 420 is connected to the microwave generator 410 and a passageway is formed therein. The microwave generated by the microwave generator 410 is transmitted to the phase converter 440 along the first waveguide 420.

The second waveguide 430 includes an outer conductor 432 and an inner conductor 434.

The outer conductor 432 extends downward in the vertical direction at the end of the first waveguide 420, and a passageway is formed therein. The upper end of the outer conductor 432 is connected to the lower end of the first waveguide 420 and the lower end of the outer conductor 432 is connected to the upper end of the cover 120.

The inner conductor 434 is located in the outer conductor 432. The inner conductor 434 is provided as a rod in the shape of a cylinder, and its longitudinal direction is arranged in parallel with the up-and-down direction. The upper end of the inner conductor 434 is inserted and fixed to the lower end of the phase shifter 440. The inner conductor 434 extends downward and its lower end is located inside the process chamber 100. The lower end of the inner conductor 434 is fixedly coupled to the center of the antenna 500. The inner conductor 434 is disposed perpendicularly to the upper surface of the antenna 500. The inner conductor 434 may be provided by sequentially coating a first plated film and a second plated film on a copper rod. According to one embodiment, the first plating film may be made of nickel (Ni), and the second plating film may be provided of gold (Au). The microwave is propagated mainly to the antenna 500 through the first plated film.

The microwave whose phase is converted by the phase converter 440 is transmitted to the antenna 500 along the second waveguide 430.

The phase shifter 440 is provided at a point where the first waveguide 420 and the second waveguide 430 are connected to change the phase of the microwave. The phase shifter 440 may be provided in the shape of a pointed cone. The phase shifter 440 propagates the microwave transmitted from the first waveguide 420 to the second waveguide 430 in a mode-converted state. The phase converter 440 may convert the microwave into TE mode to TEM mode.

The matching network 450 is provided in the first waveguide 420. The matching network 450 matches the microwave propagated through the first waveguide 420 to a predetermined frequency.

3 is a view showing the bottom surface of the antenna 500. Fig. 1 and 3, the antenna 500 is provided in a plate shape. For example, the antenna 500 may be provided as a thin disc. The antenna 500 is disposed on the top of the substrate support unit 200 so as to face the support plate 210. A plurality of slots 501 are formed in the antenna 500. The slots 501 may be provided in a 'x' shape. Alternatively, the shape and arrangement of the slots may be varied. A plurality of slots 501 are arranged in a plurality of ring shapes in combination with each other. The areas of the antenna 500 where the slots 501 are formed are referred to as first areas A1, A2 and A3 and the areas of the antenna 500 where the slots 501 are not formed are referred to as second areas B1, ). The first areas A1, A2, and A3 and the second areas B1, B2, and B3 each have a ring shape. A plurality of first regions A1, A2, and A3 are provided and have different radii from each other. The first areas A1, A2, and A3 have the same center and are spaced apart from each other in the radial direction of the antenna 500. [ A plurality of second regions B1, B2, and B3 are provided and have different radii from each other. The second regions B1, B2, and B3 have the same center and are disposed apart from each other in the radial direction of the antenna 500. [ The first areas A1, A2, and A3 are located between the adjacent second areas B1, B2, and B3, respectively. A hole 502 is formed in the center of the antenna 500. The lower end of the inner conductor 434 passes through the hole 502 and is coupled to the antenna 500. The microwaves are transmitted through the slots 501 to the dielectric plate 700.

Referring again to FIG. 1, the wave plate 600 is disposed on an upper portion of the antenna 500, and is provided with a disk having a predetermined thickness. The chop panel 600 may have a radius corresponding to the inside of the cover 120. The microwaves propagated in the vertical direction through the inner conductor 434 propagate in the radial direction of the wave plate 600. The wavelength of the microwave propagated to the wave plate 600 is compressed and resonated. And reflects the microwave reflected from the dielectric plate 700 back to the dielectric plate 700.

4 is a bottom view of the base plate 710 of FIG. 2, and FIG. 5 is a perspective view of the bottom plate 720 of FIG. 1, 4, and 5, the dielectric plate 700 includes a base plate 710 and a bottom plate 720. [ The dielectric plate 710 is provided under the antenna. The microwave is diffused and transmitted through the dielectric plate 700 into the process chamber 100. The process gas supplied into the process chamber 100 by the electric field of the emitted microwaves is excited into a plasma state.

The base plate 710 is disposed below the antenna 500 and is provided as a disk having a predetermined thickness. The bottom surface of the base plate 710 is provided with a concave surface recessed inward. The lower end of the base plate 710 may be positioned at the same height as the lower end of the cover 120. The side of the base plate 710 is stepped so that the upper end has a larger radius than the lower end. The upper end of the base plate 710 is placed at the step lower end of the cover 120. The lower end of the base plate 710 has a smaller radius than the lower end of the cover 120 and maintains a predetermined distance from the lower end of the cover 120. According to the embodiment, the tine wave plate 600, the antenna 500, and the base plate 700 can be in close contact with each other. The base plate 710 is generally provided with a dielectric material. For example, the base plate 710 may be provided with a material including a quartz. A groove 712 into which the lower plate 720 is inserted is formed on the bottom surface of the base plate 710.

The lower plate 720 is coupled to the bottom surface of the base plate 710 and is provided as a disk having a predetermined thickness. The thickness of the bottom plate 720 is not more than 30% of the thickness of the base plate 710. Therefore, even though the lower plate 720 is provided with a material different from that of the base plate 710, the transmittance and the refractive index of the microwave electric field throughout the dielectric plate 700 do not deviate from the range of the process conditions. The bottom plate 720 is provided so as to be detachable on the bottom surface of the base plate 720. For example, one of the upper surface of the lower plate 720 and the lower surface of the base plate 710 may have a fitting protrusion 721 and the other may have a fitting groove 711 into which the fitting protrusion 721 can be inserted have. Alternatively, the bottom plate 720 may be joined to the bottom of the base plate 710 by partial welding. Therefore, when the central region of the bottom surface of the dielectric plate 700, which is liable to be damaged by plasma, is damaged, only the lower plate 720, which is a part of the lower plate 720, can be easily replaced and the replacement cost can be reduced.

6 and 7 are cross-sectional views showing a cross section of the dielectric plate 700 of FIG. The distance between the base plate 710 and the lower plate 720 may be different depending on the region. Further, the lower plate 720 may be provided with different thicknesses for the respective regions. For example, referring to FIG. 6, a portion of the upper surface of the lower plate 720 may be provided so as to protrude upward in comparison with other regions. 7, the base plate 710 and the lower plate 720 are provided to be in close contact with each other, and the shape of the surface where the base plate 710 and the lower plate 720 abut can be deformed. The density of the transmitted microwave electric field can be adjusted by changing the distance between the base plate and the lower plate 720, the thickness of the lower plate 720, or the shape of the surface where the base plate 710 and the lower plate 720 abut .

The bottom plate 720 may be provided in a material different from that of the base plate 710. When the lower plate 720 is provided with a material different from that of the base plate 710, the lower plate 720 may be provided with a material having a higher plasma resistance than the base plate 710. Therefore, it is possible to prevent the central region of the bottom surface of the dielectric plate 700, which is likely to be damaged by the plasma, from being damaged. For example, the bottom plate 720 may be made of a material containing ceramics or a material containing aluminum nitride (AlN).

Alternatively, the bottom plate 720 may be provided with the same material as the base plate 710. In this case, the bottom plate 720 may be provided with a material including quartz.

W: substrate 10: substrate processing apparatus
100: process chamber 200: substrate support unit
300: gas supply unit 400: microwave application unit
500: Antenna 600:
700: dielectric plate 710: base plate
720:

Claims (13)

A process chamber having a space therein;
A substrate support unit for supporting the substrate in the process chamber;
An antenna disposed on the substrate supporting unit and having a plurality of slots;
A microwave applying unit for applying a microwave to the antenna;
And a dielectric plate provided under the antenna and diffusing and transmitting microwaves into the space inside the process chamber,
Wherein the dielectric plate comprises:
A base plate provided in a dielectric material;
And a lower plate coupled to a bottom surface of the base plate. The method according to claim 1,
Wherein a groove is formed on a bottom surface of the base plate, and the bottom plate is inserted into the groove. The method according to claim 1,
Wherein the thickness of the bottom plate is not more than 30% of the thickness of the base plate. The method according to claim 1,
Wherein the distance between the base plate and the bottom plate is different depending on the region. The method according to claim 1,
Wherein the lower plate is provided with a different thickness for each of the regions. The method according to claim 1,
Wherein a part of the upper surface of the lower plate protrudes upward relative to the other area. The method according to claim 1,
Wherein the base plate and the lower plate are provided in different materials. 8. The method of claim 7,
Wherein the lower plate is provided with a material having a higher plasma resistance than the base plate. 9. The method according to any one of claims 1 to 8,
Wherein the lower plate is detachably attached. 10. The method of claim 9,
Wherein one of the upper surface of the lower plate and the lower surface of the base plate has a fitting protrusion and the other has a fitting groove into which the fitting protrusion can be inserted. 9. The method according to any one of claims 1 to 8,
Wherein the lower plate is made of a material including ceramics. 9. The method according to any one of claims 1 to 8,
Wherein the lower plate is made of a material containing aluminum nitride (AlN). 9. The method according to any one of claims 1 to 8,
Wherein the lower plate is made of a material including quartz.

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