KR102654902B1 - Support unit, and apparatus for treating substrate with the same - Google Patents

Abstract

The present invention provides an apparatus for processing a substrate. An apparatus for processing a substrate includes a housing providing a processing space, a support unit disposed in the processing space to support the substrate, and a plasma source provided on an upper part of the housing and generating plasma from a process gas, the support unit The upper surface is composed of a first area including the center and a second area surrounding the first area, and the support unit is formed between the first area and the second area and is indented inward from the upper surface of the support unit. A groove is formed, and the support unit is formed in the first area, a plurality of first support protrusions supporting the lower surface of the substrate, and a plurality of first support protrusions formed in the second area and supporting the lower surface of the substrate. It includes two support protrusions and an adsorption hole formed on the lower surface of the groove to vacuum suction the substrate, and the first shape formed by an imaginary straight line connecting the plurality of first support protrusions is formed by the plurality of second support protrusions. It can form symmetry with the second form formed by the connected virtual straight lines.

Description

Support unit and substrate processing apparatus including same {SUPPORT UNIT, AND APPARATUS FOR TREATING SUBSTRATE WITH THE SAME}

The present invention relates to a support unit and an apparatus for processing a substrate including the same, and more particularly, to a substrate processing apparatus having a support unit for supporting a substrate.

Semiconductor integrated circuits are generally very small and thin silicon chips, but are made up of various electronic components. Various processes such as cleaning process, deposition process, photo process, etching process, and ion implantation process are performed until one semiconductor chip is produced. A device in which a semiconductor manufacturing process is performed is equipped with a chuck to support a substrate such as a semiconductor wafer.

Figure 1 is a diagram schematically showing damage to the bottom of a substrate due to contact between a substrate and a support unit in a typical substrate processing apparatus. Referring to FIG. 1, the chuck is a component that directly contacts the wafer and has a significant impact on the yield of the semiconductor process. The chuck causes damage to the bottom surface of the wafer by directly contacting the bottom surface of the wafer. Particles generated in the process of damage to the bottom of the wafer float in the processing space and interfere with the process. Additionally, the generated particles attach to the bottom of the wafer and have a negative effect on subsequent processes.

In particular, in the process of processing wafers using plasma, temperature uniformity of the wafer is important. If the temperature of the wafer is different for each unit area, warpage of the wafer occurs. Additionally, if the temperature of the wafer is not uniformly within a certain range for each unit area, it prevents the plasma from properly acting on the wafer.

One object of the present invention is to provide a support unit that can minimize damage to a substrate supported on the support unit and a substrate processing device including the same.

Another object of the present invention is to provide a support unit capable of supporting a substrate with a minimum contact area while ensuring temperature uniformity of the substrate, and a substrate processing device including the same.

Another object of the present invention is to provide a support unit that can prevent bending of a substrate supported on the support unit and a substrate processing apparatus including the same.

The problems to be solved by the present invention are not limited to the above-mentioned problems, and problems not mentioned can be clearly understood by those skilled in the art from this specification and the attached drawings. will be.

The present invention provides an apparatus for processing a substrate. An apparatus for processing a substrate includes a housing providing a processing space, a support unit disposed in the processing space to support the substrate, and a plasma source provided on an upper part of the housing and generating plasma from a process gas, the support unit The upper surface is composed of a first area including the center and a second area surrounding the first area, and the support unit is formed between the first area and the second area and is indented inward from the upper surface of the support unit. A groove is formed, and the support unit is formed in the first area, a plurality of first support protrusions supporting the lower surface of the substrate, and a plurality of first support protrusions formed in the second area and supporting the lower surface of the substrate. It includes two support protrusions and an adsorption hole formed on the lower surface of the groove to vacuum suction the substrate, and the first shape formed by an imaginary straight line connecting the plurality of first support protrusions is formed by the plurality of second support protrusions. It can form symmetry with the second form formed by the connected virtual straight lines.

According to one embodiment, the support unit may further include a heat transfer unit that transfers heat to the substrate through the support unit.

According to one embodiment, a third region surrounding the second region is further provided on the upper surface of the support unit, the groove is further formed between the second region and the third region in the support unit, and the support unit is further provided with a third region surrounding the second region. The unit is formed in the third area and further includes a plurality of third support protrusions supporting an edge lower surface of the substrate, and a second shape formed by an imaginary straight line connecting the second shape and the plurality of third support protrusions. The three forms can form symmetry with each other.

According to one embodiment, upper surfaces of the first support protrusion, the second support protrusion, and the third support protrusion may be formed to be round.

According to one embodiment, the first shape, the second shape, and the third shape may be triangles.

According to one embodiment, the support unit is connected to the suction hole and may include a vacuum line installed inside the support unit and a pressure reducing member that transmits negative pressure to the vacuum line.

Additionally, the present invention provides a support unit for supporting the substrate on the upper surface. The support unit is composed of a first area including a center on the upper surface of the support unit and a second area surrounding the first area, and the support unit is formed between the first area and the second area, and the support unit is formed between the first area and the second area. A groove is formed inward from the upper surface of the unit, the support unit is formed in the first area, a plurality of first support protrusions supporting the lower surface of the substrate are formed in the second area, and the support unit is formed in the first area. It includes a plurality of second support protrusions supporting the lower surface and an adsorption hole formed on the lower surface of the groove to vacuum suction the substrate, and the first shape formed by an imaginary straight line connecting the plurality of first supporting protrusions is It can form symmetry with the second shape formed by an imaginary straight line connecting a plurality of second support protrusions.

According to one embodiment, the support unit may further include a heat transfer unit that transfers heat to the substrate through the support unit.

According to one embodiment, a third region surrounding the second region is further provided on the upper surface of the support unit, the groove is further formed between the second region and the third region in the support unit, and the support unit is further provided with a third region surrounding the second region. The unit is formed in the third area and further includes a plurality of third support protrusions supporting an edge lower surface of the substrate, and a second shape formed by an imaginary straight line connecting the second shape and the plurality of third support protrusions. The three forms can form symmetry with each other.

According to one embodiment, upper surfaces of the first support protrusion, the second support protrusion, and the third support protrusion may be formed to be round.

According to one embodiment, the first shape, the second shape, and the third shape may be triangles.

According to one embodiment, the support unit is connected to the suction hole and may include a vacuum line installed inside the support unit and a pressure reducing member that transmits negative pressure to the vacuum line.

According to one embodiment of the present invention, damage to the substrate supported on the support unit can be minimized.

Additionally, according to an embodiment of the present invention, it is possible to support the substrate with a minimum contact area and at the same time ensure temperature uniformity of the substrate.

Additionally, according to an embodiment of the present invention, it is possible to prevent bending of the substrate supported on the support unit.

The effects of the present invention are not limited to the effects described above, and effects not mentioned can be clearly understood by those skilled in the art from this specification and the attached drawings.

Figure 1 is a diagram schematically showing damage to the bottom surface of a substrate due to contact between a substrate and a support unit in a typical substrate processing apparatus.
Figure 2 is a diagram schematically showing a substrate processing apparatus according to an embodiment of the present invention.
FIG. 3 is a diagram schematically showing an embodiment of a process chamber that performs a plasma processing process among the process chambers of the substrate processing apparatus of FIG. 2 .
Figure 4 is a cut perspective view schematically showing the support unit according to the embodiment of Figure 3 cut.
FIG. 5 is a diagram schematically showing the support unit according to the embodiment of FIG. 3 as seen from the top.
Figure 6 is a diagram showing the temperature change value of the substrate and the degree of bending of the substrate according to the arrangement of the support protrusions formed on the upper surface of the support unit.
FIG. 7 is a diagram showing the temperature change value of the substrate supported on the support unit and the degree of bending of the substrate according to the embodiment of FIG. 3.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the attached drawings. Embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited by the embodiments described below. This example is provided to more completely explain the present invention to those with average knowledge in the art. Therefore, the shapes of components in the drawings are exaggerated to emphasize a clearer explanation.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 2 to 7.

Figure 2 is a diagram schematically showing the substrate processing apparatus of the present invention. Referring to FIG. 2 , the substrate processing apparatus 1 has a front end module (Equipment Front End Module, EFEM) 20 and a processing module 30. The front end module 20 and the processing module 30 are arranged in one direction. Hereinafter, the direction in which the front end module 20 and the processing module 30 are arranged is defined as the first direction (2), and the direction perpendicular to the same plane as the first direction (2) is defined as the second direction (4). It is defined as

The front end module 20 has a load port (200) and a transfer frame (220). The load port 200 is disposed in front of the front end module 20 in the first direction 2. The load port 200 has a plurality of support portions 202. Each support unit 202 is arranged in a row in the second direction 4, and includes a carrier C (for example, a cassette, FOUP, etc.) is seated. The carrier C accommodates the substrate W to be provided in the process and the substrate W on which the process has been completed. The transfer frame 220 is disposed between the load port 200 and the processing module 30. The transfer frame 220 is disposed therein and includes a first transfer robot 222 that transfers the substrate W between the load port 200 and the processing module 30. The first transfer robot 222 moves along the transfer rail 224 provided in the second direction 4 to transfer the substrate W between the carrier C and the processing module 30.

The processing module 30 includes a load lock chamber 300, a transfer chamber 400, and a process chamber 500.

The load lock chamber 300 is disposed adjacent to the transfer frame 220. As an example, the load lock chamber 300 may be disposed between the transfer chamber 400 and the front end module 20. The load lock chamber 300 is a waiting space before the substrate (W) to be provided for the process is transferred to the process chamber 500, or before the substrate (W) whose processing has been completed is transferred to the front end module 20. to provide.

The transfer chamber 400 is disposed adjacent to the load lock chamber 300. The transfer chamber 400 has a polygonal body when viewed from the top. As an example, the transfer chamber 400 may have a pentagonal body when viewed from the top. On the outside of the body, a load lock chamber 300 and a plurality of process chambers 500 are disposed along the circumference of the body. A passage (not shown) through which the substrate W enters and exits is formed on each side wall of the body, and the passage connects the transfer chamber 400 and the load lock chamber 300 or the process chamber 500. Each passage is provided with a door (not shown) that opens and closes the passage and seals the interior.

A second transfer robot 420 is disposed in the inner space of the transfer chamber 400 to transfer the substrate W between the load lock chamber 300 and the process chamber 500. The second transfer robot 420 transfers the unprocessed substrate (W) waiting in the load lock chamber 300 to the process chamber 500, or transfers the processed substrate (W) to the load lock chamber 300. do. Then, the substrate W is transferred between the process chambers 500 in order to sequentially provide the substrate W to the plurality of process chambers 500 . For example, as shown in FIG. 1, when the transfer chamber 400 has a pentagonal body, load lock chambers 300 are disposed on the side walls adjacent to the front end module 20, and a process chamber 500 is placed on the remaining side walls. They are placed sequentially. The shape of the transfer chamber 400 is not limited to this, and may be provided in various forms depending on the required process module.

The process chamber 500 is disposed along the periphery of the transfer chamber 400. A plurality of process chambers 500 may be provided. Within each process chamber 500, processing for the substrate W is performed. The process chamber 500 receives the substrate W from the second transfer robot 420, processes it, and provides the processed substrate W to the second transfer robot 420. Process processing performed in each process chamber 500 may be different.

FIG. 3 is a diagram schematically showing a process chamber that performs a plasma processing process among the process chambers of the substrate processing apparatus of FIG. 2 . Hereinafter, the process chamber 500 that performs a plasma processing process will be described.

Referring to FIG. 3, the process chamber 500 performs a predetermined process on the substrate W using plasma. For example, the thin film on the substrate W may be etched or ashed. The thin film may be of various types, such as a polysilicon film, an oxide film, and a silicon nitride film. Optionally, the thin film may be a natural oxide film or a chemically created oxide film.

The process chamber 500 may include a process processing unit 520, a plasma generation unit 540, a diffusion unit 560, and an exhaust unit 580.

The process processing unit 520 provides a processing space 5200 in which the substrate W is placed and processing on the substrate W is performed. The plasma generator 540, which will be described later, discharges the process gas to generate plasma, and supplies it to the processing space 5200 of the process processor 520. Process gas remaining inside the process processing unit 520 and/or reaction by-products generated in the process of processing the substrate W are discharged to the outside of the process chamber 500 through an exhaust unit 580, which will be described later. Because of this, the pressure within the process processing unit 520 can be maintained at the set pressure.

The process processing unit 520 may include a housing 5220, a support unit 5240, an exhaust baffle 5260, and a baffle 5280.

A processing space 5200 in which a substrate processing process is performed may be provided inside the housing 5220. The outer wall of the housing 5220 may be provided as a conductor. As an example, the outer wall of the housing 5220 may be made of a metal material including aluminum. The housing 5220 may have an open top and an opening (not shown) may be formed in the side wall. The substrate W enters and exits the interior of the housing 5220 through the opening. The opening (not shown) may be opened and closed by an opening and closing member such as a door (not shown). Additionally, an exhaust hole 5222 is formed on the bottom of the housing 5220.

Process gas and/or by-products flowing in the processing space 5200 may be exhausted to the outside of the processing space 5200 through the exhaust hole 5222. The exhaust hole 5222 may be connected to components including the exhaust unit 580, which will be described later.

Figure 4 is a cut perspective view schematically showing the support unit according to the embodiment of Figure 3 cut. FIG. 5 is a diagram schematically showing the support unit according to the embodiment of FIG. 3 as seen from the top. Hereinafter, a support unit according to an embodiment of the present invention will be described in detail with reference to FIGS. 4 and 5.

4 and 5, the support unit 5240 is disposed inside the housing 5220. For example, support unit 5240 may be disposed within processing space 5200. The support unit 5240 supports the substrate W in the processing space 5200. Support unit 5240 may be a chuck.

The support unit 5240 may include a body 5241, a support shaft 5242, a heat transfer unit 5243, a support protrusion 5244, and a vacuum unit 5248.

The body 5241 has an upper surface on which the substrate W is seated. The upper surface of the body 5241 may be provided in a generally circular shape when viewed from the top. For example, the upper surface of the body 5241 may have a larger diameter than the substrate W. Additionally, the upper surface of the body 5241 may have a larger area than the upper surface of the substrate W when viewed from the top. A protrusion may be formed along the outer upper surface of the body 5241. The protrusion may be formed to protrude upward from the upper surface of the body 5241. The height from the top surface of the body 5241 to the top of the protrusion is greater than or equal to the height from the top surface of the body 5241 to the top of the substrate W when the substrate W is seated on the support protrusion 5244, which will be described later. You can. The inner surface of the protrusion may be provided to contact the outer surface of the substrate W when the substrate W is seated on the support protrusion 5244.

A heat transfer unit 5243 and a vacuum unit 5248, which will be described later, may be installed inside the body 5241. The upper surface of the body 5241 may be divided into a first area (A1), a second area (A2), and a third area (A3). The first area A1 is defined as an area including the center of the body 5241. The second area (A2) is defined as an area surrounding the first area (A1). The third area (A3) is defined as an area surrounding the second area (A2). For example, the first area (A1), the second area (A2), and the third area (A3) may be located sequentially when facing outward from the center of the body 5241. A first support protrusion 5245, which will be described later, is formed in the first area A1. A second support protrusion 5246, which will be described later, is formed in the second area A2. A third support protrusion 5247, which will be described later, is formed in the third area A3.

A groove (G) may be formed in the body 5241. A groove G may be formed on the upper surface of the body 5241. The groove G may be formed by being indented inward from the upper surface of the body 5241. The groove G may be indented downward from the upper surface of the body 5241. The groove G may be generally formed in a ring shape when viewed from the top. The groove G may be formed between the first area A1 and the second area A2. Additionally, the groove G may be formed between the second area A2 and the third area A3.

An adsorption hole (H) may be formed in the groove (G). An adsorption hole (H) may be formed on the lower surface of the groove (G). A plurality of suction holes (H) may be provided along the longitudinal direction of the groove (G). The adsorption hole (H) may communicate with a vacuum unit 5249 described later. The suction hole (H) can provide negative pressure to the groove (G). The adsorption hole (H) creates a negative pressure in the inner space of the groove (G), thereby creating a negative pressure in the space formed between the support protrusion 5244, which will be described later, the lower surface of the substrate W, and the protrusion formed on the outside of the body 5241. can be formed. Accordingly, the lower surface of the substrate W may be adsorbed and supported by vacuum force.

The support shaft 5242 is coupled to the body 5241. The support shaft 5242 may be coupled to the lower surface of the body 5241. The support shaft 5242 may be provided so that its longitudinal direction faces upward and downward. A vacuum line 5248a, which will be described later, may be formed inside the support shaft 5242. The support axis 5242 can move the object. As an example, the support shaft 5242 may move the substrate W in the vertical direction. Additionally, the support shaft 5242 can be coupled to the body 5241 to raise and lower the body 5241 to move the substrate W up and down.

Heat transfer unit 5243 heats the substrate W. The heat transfer unit 5243 may be buried inside the body 5241. The heat transfer unit 5243 heats the substrate W by increasing the temperature of the body 5241. That is, the heat transfer unit 5243 controls the temperature of the substrate W via the body 5241. Heat transfer unit 5243 is connected to a power source, not shown. The heat transfer unit 5243 generates heat by resisting a current applied from a power source not shown. The generated heat is transferred to the substrate (W) through the body (5241). The substrate W may be maintained at a predetermined temperature by the heat generated in the heat transfer unit 5243.

According to one example, a plurality of heat transfer units 5243 may be provided as spiral-shaped coils. Heat transfer units 5243 may be provided in different areas of the body 5241, respectively. For example, a heat transfer unit 5243 that heats the central area of the body 5241 and the edge area of the body 5241 is provided, and the degree of heat generation can be adjusted independently. According to one example, the heat transfer unit 5243 may be provided as a heating element such as tungsten.

The support protrusion 5244 is installed on the body 5241. The support protrusion 5244 is installed on the upper surface of the body 5241. The support protrusion 5244 supports the substrate W. The upper end of the support protrusion 5244 supports the lower end of the substrate (W). The support protrusion 5244 may be formed integrally with the body 5241. However, it is not limited to this, and the support protrusion 5244 may not be formed integrally with the body 5241.

The support protrusions 5244 may be formed in plural numbers. The support protrusion 5244 may be formed in a generally cylindrical shape. According to one example, the top of the support protrusion 5244 may be formed to be round. Accordingly, the support protrusion 5244 according to one example may make point contact with the lower surface of the substrate W.

The support protrusion 5244 may include a first support protrusion 5245, a second support protrusion 5246, and a third support protrusion 5247. The first support protrusion 5245 may be formed in the first area A1 including the center of the body 5241 on the upper surface of the body 5241. For example, as shown in FIG. 5 , three first support protrusions 5245 may be provided within the first area A1. The first shape formed by the virtual straight line connecting the plurality of first support protrusions 5245 may be formed in the form of a first triangle with one side having a first length. The first support protrusion 5245 may support an area including the center of the substrate W.

The second support protrusion 5246 may be formed in the second area A2 surrounding the first area A1 of the upper surface of the body 5241. For example, as shown in FIG. 5 , three second support protrusions 5246 may be provided within the second area A2. The second shape formed by the virtual straight line connecting the plurality of second support protrusions 5246 may form a second triangle with one side having a second length.

The third support protrusion 5247 may be formed in the third area A3 surrounding the second area A2 of the upper surface of the body 52441. For example, as shown in FIG. 5 , three third support protrusions 5247 may be provided within the third area A3. The third shape formed by the virtual straight line connecting the plurality of third support protrusions 5247 may form a third triangle with one side having a third length.

The first shape formed by the first support protrusion 5245 may be formed symmetrically with the second shape formed by the second support protrusion 5246. For example, the first form may be an upside-down form of the second form. Additionally, the second shape formed by the second support protrusion 5246 and the third shape formed by the third support protrusion 5247 may be symmetrical to each other. For example, the second form may be an upside-down form of the third form.

The vacuum unit 5248 may provide vacuum force to the inner space of the groove (G). The vacuum unit 5248 may provide negative pressure to the inner space of the groove G to adsorb the substrate W to the support unit 5240. Vacuum unit 5248 may include a vacuum line 5248a and a pressure relief member 5248b.

The vacuum line 5248a may be buried inside the vacuum unit 5240. For example, the vacuum line 5248a may be formed inside the body 5241 and the support shaft 5242. The vacuum line 5248a may be installed at a location that does not overlap the heat transfer unit 5243. One end of the vacuum line 5248a may be connected to the suction hole (H). The other end of the vacuum line 5248a may be connected to a pressure reducing member 5248b, which will be described later.

The pressure reducing member 5248b may provide negative pressure to the groove (G). The pressure reducing member 5248b provides a vacuum force to secure the substrate W to the support unit 5240. Pressure reducing member 5248b may be a pump. However, it is not limited to this, and the pressure reducing member 5248b is a known device that provides negative pressure and may be provided in various modifications.

Figure 6 is a diagram showing the temperature change value of the substrate and the degree of bending of the substrate according to the arrangement of the support protrusions formed on the upper surface of the support unit. FIG. 7 is a diagram showing the temperature change value of the substrate supported on the support unit and the degree of bending of the substrate according to the embodiment of FIG. 3.

Temp. (VAG) expressed in Figures 6 and 7 means the average temperature delivered to the substrate (W), and Temp. (Range) is the highest and lowest temperature among the temperatures for each region of the substrate (W). It refers to the difference value, and Bare Wafer Warpage refers to whether warping of the substrate occurs. Hereinafter, with reference to experimental data on the temperature distribution of the substrate and whether bending of the substrate occurs depending on the number and arrangement of the support protrusions 5244 formed on the support unit 5240, the support unit according to an embodiment of the present invention ( 5240).

Hereinafter, the temperature distribution of the substrate and whether bending occurs depending on the number and arrangement of support protrusions will be explained by sequentially referring to the experimental data from left to right.

When a large number of support protrusions 5244 are formed on the entire upper surface of the body 5241, the average temperature of the substrate W was measured at 245.9 degrees Celsius, and the temperature deviation was measured at 10.5 degrees Celsius. However, in this case, since a large number of support protrusions 5244 evenly supported the lower surface of the substrate W, bending of the substrate W did not occur.

Next, when a plurality of support protrusions 5244 are arranged at narrow intervals in the area corresponding to the center area of the substrate W, the average temperature of the substrate W was measured to be 247.5 degrees Celsius, and the temperature deviation was 10 degrees Celsius. It was measured.

Next, when the support protrusions 5244 are disposed only in the edge region of the body 5241 corresponding to the edge region of the substrate W, the temperature of the substrate W is 251.3 degrees Celsius, and the temperature deviation of the substrate W is 7.4 degrees Celsius. The road was measured. In this case, the substrate W was warped.

In contrast, referring to FIG. 7, when using the support unit 5240 according to an embodiment of the present invention, the average temperature of the substrate W was measured to be 248.9 degrees Celsius, and the temperature deviation for each region of the substrate W was measured. showed a lower temperature deviation value than the other experimental examples shown in FIG. 6 at 4.3 degrees Celsius. In addition, while the temperature of the substrate W was formed uniformly, the phenomenon of bending of the substrate W did not occur.

That is, according to one embodiment of the present invention, the first support protrusion 5245, the second support protrusion 5246, and the third support protrusion 5247 are formed in separate areas on the upper part of each body 5241. Since the shapes of the support protrusions 5244 formed in each region are symmetrical to each other, the substrate W can be stably supported using a minimum number of support protrusions 5244. In addition, while supporting the substrate W using a minimum number of support protrusions 5244, heat transferred to the substrate W can be uniformly distributed. Additionally, by using a minimum number of support protrusions 5244, contact shock applied to the lower surface of the substrate W can be minimized. Accordingly, the defect rate of the processing process that occurs due to damage to the substrate W can be improved.

Since the top of the support protrusion 5244 is formed to be round, the top of the support protrusion 5244 and the lower surface of the substrate W can make point contact. When supporting the substrate W, damage to the lower surface of the substrate W caused by contact can be minimized. Accordingly, when a predetermined process is performed on the substrate W by supporting the substrate W, leakage of particles, etc., generated from damage to the substrate W into the processing space can be minimized.

The support unit 5240 according to an embodiment of the present invention described above is described as an example of supporting the substrate W using vacuum pressure by adsorbing the lower surface of the substrate W using a vacuum adsorption method. However, it is not limited to this, and the support unit 5240 is mechanically fixed by pressing the support surface of the substrate W using an arm or clamp, or by using static electricity between the substrate W and the support unit 5240. The substrate W may be supported by generating and fixing the substrate W with electrostatic force.

In addition, according to the above-described embodiment of the present invention, the upper surface of the body 5241 is divided into a first area (A1), a second area (A2), and a third area (A3). It is not limited to this. For example, the upper surface of the body 5241 is divided into a first area (A1) and a second area (A2) surrounding the first area (A1), and a first support protrusion forming a first shape is in the first area (A1). 5245 may be provided, and a second support protrusion 5246 forming a second shape symmetrical to the first shape may be provided in the second area A2.

In this way, a plurality of regions surrounding the third area A3 may be further provided on the upper surface of the body 5241, and support protrusions symmetrical to each other may be further formed in the plurality of regions.

Referring again to FIG. 3, the exhaust baffle 5260 uniformly exhausts plasma from the processing space 5200 by region. The exhaust baffle 5260 has an annular ring shape when viewed from the top. Exhaust baffle 5260 may be located within processing space 5200 between the inner wall of housing 5220 and support unit 5240. A plurality of exhaust holes 5262 are formed in the exhaust baffle 5260. Exhaust holes 5262 may be provided to face upward and downward. The exhaust holes 5262 may be provided as holes extending from the top to the bottom of the exhaust baffle 5260. The exhaust holes 5262 may be arranged to be spaced apart from each other along the circumferential direction of the exhaust baffle 5260.

The baffle 5280 may be disposed between the process processing unit 520 and the plasma generating unit 540. Additionally, the baffle 5280 may be disposed between the process processing unit 520 and the diffusion unit 560. Additionally, the baffle 5280 may be disposed between the support unit 5240 and the diffusion portion 560. The baffle 5280 may be disposed on top of the support unit 5240. As an example, the baffle 5280 may be placed at the top of the process processing unit 520.

The baffle 5280 can uniformly transmit plasma generated in the plasma generator 540 to the processing space 5200. A baffle hole 5282 may be formed in the baffle 5280. A plurality of baffle holes 5282 may be provided. Baffle holes 5282 may be provided to be spaced apart from each other. Baffle holes 5282 may penetrate from the top to the bottom of the baffle 5280. The baffle holes 5282 may function as a passage through which plasma generated in the plasma generator 540 flows into the processing space 5200.

The baffle 5280 may have a plate shape. The baffle 5280 may have a disk shape when viewed from the top. When the baffle 5280 is viewed in cross section, the height of its upper surface may increase from the edge area to the center area. For example, when the baffle 5280 is viewed in cross section, its upper surface may have a shape that slopes upward from the edge area to the center area.

Accordingly, the plasma generated in the plasma generator 540 may flow to the edge area of the processing space 5200 along the inclined cross section of the baffle 5280. Unlike the above-described example, the cross section of the baffle 5280 may not be inclined. As an example, the baffle 5280 may be provided in a disk shape with a predetermined thickness.

The plasma generator 540 may generate plasma by exciting a process gas supplied from a gas supply unit 5440, which will be described later, and supply the generated plasma to the processing space 5200.

The plasma generator 540 may be located above the process processing unit 520. The plasma generator 540 may be located above the housing 5220 and the diffusion portion 560, which will be described later. The process processing unit 520, the diffusion unit 560, and the plasma generating unit 540 are sequentially positioned from the ground along the third direction 6, which is perpendicular to both the first direction 2 and the second direction 4. can do.

The plasma generator 540 may include a plasma chamber 5420, a gas supply unit 5440, and a power application unit 5460.

The plasma chamber 5420 may have an open top and bottom surface. For example, the plasma chamber 5420 may have a cylindrical shape with an open upper and lower surface. Openings may be formed at the top and bottom of the plasma chamber 5420. The plasma chamber 5420 may have a plasma generation space 5422. The plasma chamber 5420 may be made of a material containing aluminum oxide (Al2O3).

The upper surface of the plasma chamber 5420 may be sealed by a gas supply port 5424. The gas supply port 5424 may be connected to a gas supply unit 5440 described later. Process gas may be supplied to the plasma generation space 5422 through the gas supply port 5424. The process gas supplied to the plasma generation space 5422 may be uniformly distributed into the processing space 5200 through the baffle hole 5282.

The gas supply unit 5440 may supply process gas. The gas supply unit 5440 may be connected to the gas supply port 5424. The process gas supplied by the gas supply unit 5440 may include fluorine and/or hydrogen.

The power application unit 5460 applies high frequency power to the plasma generation space 5422. The power application unit 5460 may be a plasma source that generates plasma by exciting a process gas in the plasma generation space 5422. The power applying unit 5460 may include an antenna 5462 and a power source 5464.

Antenna 5462 may be an inductively coupled plasma (ICP) antenna. The antenna 5462 may be provided in a coil shape. The antenna 5462 may wrap around the plasma chamber 5420 multiple times from the outside of the plasma chamber 5420. The antenna 5462 may spirally wrap around the plasma chamber 5420 multiple times outside the plasma chamber 5420.

The antenna 5462 may be wound around the plasma chamber 5420 in an area corresponding to the plasma generation space 5422. One end of the antenna 5462 may be provided at a height corresponding to the upper area of the plasma chamber 5420 when viewed from the front end of the plasma chamber 5420. The other end of the antenna 5462 may be provided at a height corresponding to the lower area of the plasma chamber 5420 when viewed from the front end of the plasma chamber 5420.

Power source 5464 may apply power to antenna 5462. The power source 5464 may apply high-frequency alternating current to the antenna 5462. The high-frequency alternating current applied to the antenna 5462 may form an induced electric field in the plasma generation space 5422. The process gas supplied into the plasma generation space 5422 may be converted into a plasma state by obtaining energy required for ionization from the induced electric field.

Power source 5464 may be connected to one end of antenna 5462. The power source 5464 may be connected to one end of the antenna 5462 provided at a height corresponding to the upper area of the plasma chamber 5420. Additionally, the other end of the antenna 5462 may be grounded. The other end of the antenna 5462 provided at a height corresponding to the lower area of the plasma chamber 5420 may be grounded. However, it is not limited to this, and one end of the antenna 5462 may be grounded, and a power source 5464 may be connected to the other end of the antenna 5462.

The diffusion unit 560 may diffuse the plasma generated in the plasma generator 540 into the processing space 5200. The diffusion unit 560 may include a diffusion chamber 5620. The diffusion chamber 5620 provides a plasma diffusion space 5622 that diffuses the plasma generated in the plasma chamber 5420. The plasma generated in the plasma generator 540 may spread through the plasma diffusion space 5622. Plasma flowing into the plasma diffusion space 5622 may be uniformly distributed into the processing space 5200 through the baffle 5280.

The diffusion chamber 5620 may be located below the plasma chamber 5420. Diffusion chamber 5620 may be located between housing 5220 and plasma chamber 5420. The housing 5220, the diffusion chamber 5620, and the plasma chamber 5420 may be sequentially positioned from the ground along the third direction 6. The inner peripheral surface of the diffusion chamber 5620 may be provided as a non-conductor. For example, the inner peripheral surface of the diffusion chamber 5620 may be made of a material containing quartz.

The exhaust unit 580 may exhaust process gases and impurities inside the processing unit 520 to the outside. The exhaust unit 580 may exhaust impurities and particles generated in the process of processing the substrate W to the outside of the process chamber 500 . The exhaust unit 580 may exhaust the process gas supplied into the processing space 5200 to the outside of the process chamber 500 . The exhaust unit 580 may include an exhaust line 5820. The exhaust line 5820 may be connected to the exhaust hole 5222 formed on the bottom of the housing 5220. The exhaust line 5820 is connected to a pump that provides negative pressure (not shown) and discharges plasma, impurities, and particles remaining in the processing space 5200 to the outside of the housing 5220.

The above detailed description is illustrative of the present invention. Additionally, the foregoing is intended to illustrate preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications, and environments. That is, changes or modifications are possible within the scope of the inventive concept disclosed in this specification, the scope equivalent to the written disclosure, and/or the technology or knowledge in the art. The above-described embodiments illustrate the best state for implementing the technical idea of the present invention, and various changes required for specific application fields and uses of the present invention are also possible. Accordingly, the detailed description of the invention above is not intended to limit the invention to the disclosed embodiments. Additionally, the appended claims should be construed to include other embodiments as well.

20: front end module
30: processing module
500: Process chamber
5240: Support unit
5241: body
5242: support axis
5243: heat transfer unit
5244: Support protrusion
5245: first support protrusion
5246: Second support protrusion
5247: Third support protrusion
5248: Vacuum unit
G: groove
H: suction hole
A1: Area 1
A2: Second area
A3: Area 3

Claims (12)

In a device for processing a substrate,
a housing providing processing space;
a support unit disposed within the processing space to support the substrate; and
Includes a plasma source provided on the upper part of the housing and generating plasma from the process gas,
The upper surface of the support unit is composed of a first area including the center of the support unit and a second area surrounding the first area,
A groove is formed in the support unit between the first area and the second area and indented inward from the upper surface of the support unit,
The support unit is,
a plurality of first support protrusions formed in the first area and supporting a lower surface of the substrate;
a plurality of second support protrusions formed in the second area and supporting a lower surface of the substrate; and
It includes an adsorption hole formed on the lower surface of the groove to vacuum adsorb the substrate,
The first shape formed by the virtual straight lines connecting the plurality of first support protrusions is 180 degrees symmetrical to the second shape formed by the virtual straight lines connecting the plurality of second supporting protrusions. According to paragraph 1,
The support unit is,
A substrate processing apparatus further comprising a heat transfer unit that transfers heat to the substrate via the support unit. According to paragraph 2,
A third area surrounding the second area is further provided on the upper surface of the support unit,
The groove is further formed in the support unit between the second area and the third area,
The support unit is,
Further comprising a plurality of third support protrusions formed in the third area and supporting a lower edge of the substrate,
A substrate processing apparatus in which the second shape and the third shape formed by an imaginary straight line connecting the plurality of third support protrusions are symmetrical to each other. According to paragraph 3,
A substrate processing apparatus wherein upper surfaces of the first support protrusion, the second support protrusion, and the third support protrusion are formed to be rounded. According to paragraph 3,
The first form, the second form, and the third form are triangular. According to paragraph 1,
The support unit is,
a vacuum line connected to the suction hole and installed inside the support unit; and
A substrate processing device including a pressure reducing member that transmits negative pressure to the vacuum line. In the support unit supporting the substrate on the upper surface,
The upper surface of the support unit is composed of a first area including the center of the support unit and a second area surrounding the first area,
A groove is formed in the support unit between the first area and the second area and indented inward from the upper surface of the support unit,
The support unit is,
a plurality of first support protrusions formed in the first area and supporting a lower surface of the substrate;
a plurality of second support protrusions formed in the second area and supporting a lower surface of the substrate; and
It includes an adsorption hole formed on the lower surface of the groove to vacuum adsorb the substrate,
The first shape formed by the virtual straight lines connecting the plurality of first support protrusions is 180 degrees symmetrical to the second shape formed by the virtual straight lines connecting the plurality of second supporting protrusions. In clause 7,
The support unit is,
The support unit further includes a heat transfer unit that transfers heat to the substrate through the support unit. According to clause 8,
A third area surrounding the second area is further provided on the upper surface of the support unit,
The groove is further formed in the support unit between the second area and the third area,
The support unit is,
Further comprising a plurality of third support protrusions formed in the third area and supporting a lower edge of the substrate,
A support unit in which the second form and the third form formed by an imaginary straight line connecting the plurality of third support protrusions are symmetrical to each other. According to clause 9,
A support unit wherein upper surfaces of the first support protrusion, the second support protrusion, and the third support protrusion are formed to be rounded. According to clause 10,
The first shape, the second shape, and the third shape are triangular support units. In clause 7,
The support unit is,
a vacuum line connected to the suction hole and installed inside the support unit; and
A support unit including a pressure reducing member that transmits negative pressure to the vacuum line.

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