KR20200072957A - Apparatus for treating substrate and method for treating substrate - Google Patents

Abstract

The present invention is to provide a substrate processing apparatus. According to one embodiment, the substrate processing apparatus comprises: a first processing unit for processing a substrate with liquid; and a second processing unit for processing the substrate with liquid. Each of the first and second processing units includes: a cup having a processing space therein; a support unit supporting the substrate in the processing space and including a rotatable support plate; a liquid discharge unit discharging a processing liquid to the substrate supported by the support unit; and a conductive member coming in direct contact with at least one of the processing liquid supplied on the substrate and the substrate. The conductive member is provided to be grounded and the conductive member grounded in the first processing unit and the conductive member grounded in the second processing unit are provided to have different electrical conductivity. According to the present invention, the substrate processing efficiency can be increased.

Description

Substrate processing apparatus and substrate processing method{APPARATUS FOR TREATING SUBSTRATE AND METHOD FOR TREATING SUBSTRATE}

The present invention relates to a substrate processing apparatus and a substrate processing method.

In general, semiconductor devices are manufactured by depositing various materials on a substrate in a thin film form and patterning them. To this end, different processes of various stages such as a deposition process, a photo process, an etching process and a cleaning process are required.

Among these processes, the etching process is a process of removing the film formed on the substrate, and the cleaning process is a process of removing contaminants remaining on the substrate surface after each unit process for semiconductor manufacturing. The etching process and the cleaning process are classified into a wet method and a dry method according to the process progress method, and the wet method is classified into a batch type method and a spin type method.

In the spin type method, after fixing the substrate to a support unit capable of processing a single substrate, the substrate is rotated to supply the treatment liquid or deionized water to the substrate through a liquid supply nozzle, and the treatment liquid or deionized water is centrifugally applied. The substrate is cleaned by spreading it over the entire surface of the substrate, and after the substrate is cleaned, the substrate is dried with a dry gas.

In the spin type wet processing process, in order to adjust the etching rate of the substrate, the temperature of the processing liquid, the concentration of the processing liquid, the discharge flow rate of the processing liquid, or the rotational speed of the substrate is adjusted as an etching rate adjustment factor. As the etching rate is adjusted by controlling the treatment liquid, chambers applied in a single installation are provided with the same etching rate.

An object of the present invention is to provide a substrate processing apparatus and a substrate processing method capable of increasing substrate processing efficiency.

One object of the present invention is to provide a substrate processing apparatus and a substrate processing method in which a plurality of chambers in a single facility can provide different etch rates, respectively.

An object of the present invention is to provide a substrate processing apparatus and a substrate processing method capable of reducing equipment manufacturing cost and reducing footprint.

It is an object of the present invention to provide a new factor for controlling the etch rate.

The present invention provides a substrate processing apparatus. In one embodiment, an apparatus for processing a substrate includes: a first processing unit for liquid-processing the substrate; It includes a second processing unit for liquid processing the substrate, the first processing unit and the second processing unit, each having a cup having a processing space therein; A support unit supporting a substrate in the processing space and including a rotatable support plate; A liquid discharging unit for discharging a treatment liquid to the substrate supported on the support unit; And a conductive member in direct contact with at least one of the processing liquid supplied on the substrate or the substrate; The conductive member is provided to be grounded, and the conductive member grounded in the first processing unit and the conductive member grounded in the second processing unit are provided with different electrical conductivity.

In one embodiment, the support unit includes a plurality of pin members provided on the support plate to support a substrate positioned on the upper surface of the support plate, and the conductive member may be provided as one or more of the pin members.

In one embodiment, the conductive member grounded in the first processing unit and the conductive member grounded in the second processing unit may be chuck pins supporting side surfaces of the substrate.

In one embodiment, the first processing unit and the second processing unit may be provided to perform the same process.

In one embodiment, the processing liquid supplied by the liquid discharge unit provided to each of the first processing unit and the second processing unit may be chemically ionized to react with the substrate.

The present invention provides a substrate processing method. In one embodiment, a method of processing a substrate is performed by etching a substrate by supplying a processing liquid to a substrate positioned in a processing chamber and being rotated, while being supplied on the substrate while the processing liquid is supplied to the substrate The processing liquid or the substrate is in contact with a grounded fin member, and the adjustment factor of the etch rate of the substrate includes the electrical conductivity of the fin member.

In one embodiment, the pin member may be one or more of a plurality of pin members supporting the substrate.

In one embodiment, the electrical conductivity of the grounded fin member may be increased to reduce the etch rate.

In one embodiment, when the etching rate of the substrate is to be the first etching rate, a pin member having the electrical conductivity of the first size is used, and when the etching rate of the substrate is to be the second etching rate, the second size A pin member having an electrical conductivity of is used, but the first etch rate may be greater than the second etch rate, and the first size may be less than the second size.

In one embodiment, two or more processing chambers are provided, and a conductive member provided in one of the processing chambers may be provided with higher or lower electrical conductivity than a conductive member provided in the other of the processing chambers.

In one embodiment, the treatment liquid supplied by the liquid discharge unit may be a chemical that is ionized and reacts with the substrate.

In one embodiment, the treatment liquid may include hydrofluoric acid.

A substrate processing apparatus according to another aspect of the present invention includes a liquid processing unit for liquid processing a substrate, the liquid processing unit comprising: a cup having a processing space therein; A support unit supporting a substrate in the processing space and including a rotatable support plate; A liquid discharging unit for discharging a treatment liquid to the substrate supported on the support unit;

And a conductive member in direct contact with at least one of the processing liquid supplied on the substrate or the substrate,

The conductive member is provided to be grounded, and a variable impedance is installed in a grounding path provided between the grounded conductive member and the ground.

In one embodiment, the variable impedance may be provided as one or more of a variable resistor, variable capacitor or variable inductor.

In one embodiment, the controller further includes a controller for controlling the variable impedance, and the controller can increase the impedance when the etch rate is to be increased.

In one embodiment, further comprising a controller for controlling the variable impedance, the controller can adjust the impedance of the variable impedance according to the process.

In one embodiment, the support unit includes a plurality of pin members provided on the support plate to support a substrate positioned on the upper surface of the support plate, and the conductive member may be provided as one or more of the pin members.

In one embodiment, the treatment liquid supplied by the liquid discharge unit may be a chemical that is ionized and reacts with the substrate.

According to the present invention, the substrate processing efficiency can be increased.

According to the present invention, a plurality of chambers in a single installation can provide different etch rates, respectively.

According to the present invention, it is possible to reduce the equipment manufacturing cost and reduce the footprint.

According to the present invention, the etching rate can be finely adjusted from a new factor for controlling the etching rate.

1 is a plan view schematically showing a substrate processing facility according to an embodiment of the present invention.
FIG. 2 is a diagram briefly showing a cross-sectional view of the first substrate processing apparatus 3100 and the second substrate processing apparatus 3200 according to the first embodiment and their relationship.
3 is a plan view schematically showing a support unit of the first substrate processing apparatus 3100 and the second substrate processing apparatus 3200 of FIG. 2.
4 is a cross-sectional view schematically showing the interior of the support unit of the first substrate processing apparatus 3100 and the second substrate processing apparatus 3200 of FIG. 2.
5 is a view showing a state in which the processing liquid is supplied from the first substrate processing apparatus 3100 of FIG. 2.
6 is a view showing a state in which the processing liquid is supplied from the second substrate processing apparatus 3200 of FIG. 2.
7 is a graph showing the difference in etching rate when a chuck pin to which material A and material B are applied is used.
8 is a cross-sectional view schematically showing the structure of a substrate processing apparatus according to a second embodiment.
9 and 10 are views showing a state in which the processing liquid is supplied from the substrate processing apparatus according to the second embodiment.

The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be interpreted as being limited by the examples described below. This embodiment is provided to more fully describe the present invention to those skilled in the art. Therefore, the shapes of components in the drawings are exaggerated to emphasize a clearer description. The same reference numerals refer to the same components throughout the specification.

With reference to the accompanying Figures 1 to 10 will be described in detail an embodiment of the present invention. The present invention is not limited by the embodiments disclosed in this specification.

1 is a plan view schematically showing a substrate processing facility 1 according to an embodiment of the present invention.

Referring to FIG. 1, the substrate processing facility 1 has an index module 10 and a process processing module 20, and the index module 10 has a load port 120 and a transfer frame 140. The load port 120, the transfer frame 140, and the process processing module 20 are sequentially arranged in a line. Hereinafter, the direction in which the load port 120, the transfer frame 140, and the process processing module 20 are arranged is referred to as a first direction 12, and when viewed from the top, perpendicular to the first direction 12 The direction is referred to as a second direction 14, and a direction that rises perpendicular to a plane including the first direction 12 and the second direction 14 is called a third direction 16.

The carrier 130 in which the substrate W is accommodated is mounted on the load port 140. A plurality of load ports 120 are provided and they are arranged in a line along the second direction 14. The number of load ports 120 may increase or decrease depending on the process efficiency of the process processing module 20 and footprint conditions. The carrier 130 is formed with a plurality of slots (not shown) for accommodating the substrates W in a horizontal arrangement with respect to the ground. As the carrier 130, a front opening unified pod (FOUP) may be used.

The process processing module 20 has a buffer unit 220, a transfer chamber 240, and a process chamber 260. The transfer chamber 240 is disposed in the longitudinal direction parallel to the first direction (12). Process chambers 260 are disposed on both sides of the transfer chamber 240, respectively. The process chambers 260 on one side and the other side of the transfer chamber 240 are provided to be symmetrical with respect to the transfer chamber 240. A plurality of process chambers 260 are provided on one side of the transfer chamber 240. Some of the process chambers 260 are disposed along the longitudinal direction of the transfer chamber 240. In addition, some of the process chambers 260 are arranged to be stacked with each other. That is, the process chambers 260 may be disposed on one side of the transfer chamber 240 in the arrangement of A X B. Where A is the number of process chambers 260 provided in a line along the first direction 12 and B is the number of process chambers 260 provided in a line along the third direction 16. When four or six process chambers 260 are provided on one side of the transfer chamber 240, the process chambers 260 may be arranged in an arrangement of 2 X 2 or 3 X 2. The number of process chambers 260 may be increased or decreased. Unlike the above, the process chamber 260 may be provided only on one side of the transfer chamber 240. In addition, unlike the above, the process chamber 260 may be provided as a single layer on one side and both sides of the transfer chamber 240.

The buffer unit 220 is disposed between the transfer frame 140 and the transfer chamber 240. The buffer unit 220 provides a space where the substrate W stays before the substrate W is transferred between the transfer chamber 240 and the transfer frame 140. The buffer unit 220 is provided with a slot (not shown) in which the substrate W is placed, and a plurality of slots (not shown) are spaced apart from each other along the third direction 16. The buffer unit 220 has a surface facing the transfer frame 140 and a surface facing the transfer chamber 240 open.

The transfer frame 140 transports the substrate W between the carrier 130 mounted on the load port 120 and the buffer unit 220. The transfer frame 140 is provided with an index rail 142 and an index robot 144. The index rail 142 is provided with its longitudinal direction parallel to the second direction 14. The index robot 144 is installed on the index rail 142, and is linearly moved in the second direction 14 along the index rail 142. The index robot 144 has a base 144a, a body 144b, and an index arm 144c. The base 144a is installed to be movable along the index rail 142. The body 144b is coupled to the base 144a. The body 144b is provided to be movable along the third direction 16 on the base 144a. Further, the body 144b is provided to be rotatable on the base 144a. The index arm 144c is coupled to the body 144b, and is provided to be movable forward and backward relative to the body 144b. A plurality of index arms 144c are provided to be individually driven. The index arms 144c are arranged to be stacked apart from each other along the third direction 16. Some of the index arms 144c are used when conveying the substrate W from the process processing module 20 to the carrier 130, and another part of it is used to transfer the substrate W from the carrier 130 to the process processing module 20 ). This can prevent particles generated from the substrate W before the process processing from being attached to the substrate W after the process processing in the process of the index robot 144 carrying in and out the substrate W.

The transfer chamber 240 transports the substrate W between the buffer unit 220 and the process chamber 260 and between the process chambers 260. The transfer chamber 240 is provided with a guide rail 242 and a main robot 244. The guide rail 242 is arranged such that its longitudinal direction is parallel to the first direction 12. The main robot 244 is installed on the guide rail 242, and is linearly moved along the first direction 12 on the guide rail 242. The main robot 244 has a base 244a, a body 244b, and a main arm 244c. The base 244a is installed to be movable along the guide rail 242. The body 244b is coupled to the base 244a. The body 244b is provided to be movable along the third direction 16 on the base 244a. Further, the body 244b is provided to be rotatable on the base 244a. The main arm 244c is coupled to the body 244b, which is provided to move forward and backward relative to the body 244b. A plurality of main arms 244c are provided and are provided to be individually driven. The main arms 244c are arranged to be stacked apart from each other along the third direction 16.

A substrate processing apparatus 300 that performs a cleaning process on the substrate W is provided in the process chamber 260. The substrate processing apparatus 300 may have a different structure depending on the type of cleaning process to be performed. Alternatively, the substrate processing apparatus 300 in each process chamber 260 may have the same structure. Optionally, the process chambers 260 are divided into a plurality of groups, and the substrate processing apparatuses 300 in the process chambers 260 belonging to the same group are identical to each other and the substrate processing apparatuses in the process chambers 260 belonging to different groups The structures of 300 may be provided differently from each other. For example, when the process chamber 260 is divided into two groups, a first group of process chambers 260 are provided on one side of the transfer chamber 240 and a second group of processes on the other side of the transfer chamber 240. Chambers 260 may be provided. Optionally, a first group of process chambers 260 may be provided on both sides of the transfer chamber 240, and a second group of process chambers 260 may be provided on the upper layer. The first group of process chambers 260 and the second group of process chambers 260 may be classified according to the type of chemical used or the type of the `method. Alternatively, the first group of process chambers 260 and the second group of process chambers 260 may be provided to sequentially perform a process on one substrate W. For example, the substrate W may be subjected to a chemical treatment process or a rinse process in the first group of process chambers 260, and a rinse process or a drying process may be performed in the second group of process chambers 260.

Hereinafter, the first substrate processing apparatus 3100 and the second substrate processing apparatus 3200 are described as an example of the substrate processing apparatus 300 for cleaning the substrate W using the processing liquid. The first substrate processing apparatus 3100 and the second substrate processing apparatus 3200 are provided as a liquid processing unit.

2 is a diagram briefly showing cross-sectional views of the first substrate processing apparatus 3100 and the second substrate processing apparatus 3200 and their relationships.

The first substrate processing apparatus 3100 and the second substrate processing apparatus 3200 are provided in each process chamber 260. The first substrate processing apparatus 3100 and the second substrate processing apparatus 3200 may belong to one group.

The first substrate processing apparatus 3100 and the second substrate processing apparatus 3200 commonly have a cup 320, a support unit 340, a lifting unit 360, and a liquid ejecting unit 380.

The cup 320 has a processing space in which a substrate processing process is performed, and an upper portion thereof is opened. The cup 320 has an inner collection container 322, an intermediate collection container 324, and an outer collection container 326. Each of the collection bins 322, 324, and 326 recovers different treatment liquids from the treatment liquids used in the process. The inner recovery container 322 is provided in an annular ring shape surrounding the support unit 340, the intermediate recovery container 324 is provided in an annular ring shape surrounding the inner recovery container 322, and the outer recovery container 326 ) Is provided in the shape of an annular ring surrounding the intermediate collection container 324.

The inner space 322a of the inner recovery container 322, the space 324a between the inner recovery container 322 and the intermediate recovery container 324, and the space between the intermediate recovery container 324 and the outer recovery container 326 ( 326a) functions as an inlet through which the treatment liquid flows into the inner collection container 322, the intermediate collection container 324, and the outer collection container 326, respectively. The collection lines 322b, 324b, and 326b vertically extending in the downward direction of the bottom surface are connected to the respective collection cylinders 322, 324, and 326. Each of the recovery lines 322b, 324b, and 326b discharges the treatment liquid introduced through each of the recovery containers 322, 324, 326. The discharged treatment liquid may be reused through an external treatment liquid regeneration system (not shown).

The lifting unit 360 linearly moves the cup 320 in the vertical direction. As the cup 320 moves up and down, the relative height of the cup 320 relative to the support unit 340 is changed. The lifting unit 360 has a bracket 362, a moving shaft 364, and a driver 366. The bracket 362 is fixedly installed on the outer wall of the cup 320, and the moving shaft 364 moved in the vertical direction by the driver 366 is fixedly coupled to the bracket 362. The cup 320 is lowered so that the support unit 340 protrudes to the top of the cup 320 when the substrate W is placed on the support unit 340 or is lifted from the support unit 340. In addition, when the process is in progress, the height of the cup 320 is adjusted so that the processing liquid can be introduced into the preset collection container 360 according to the type of the processing liquid supplied to the substrate W. Optionally, the lifting unit 360 may move the support unit 340 in the vertical direction.

The liquid discharge unit 380 supplies the treatment liquid to the substrate W during the substrate treatment process. The liquid discharge unit 380 has a support shaft 386, a driver 388, a nozzle support 382, and a nozzle 384. The support shaft 386 is provided in the longitudinal direction along the third direction 16, and a driver 388 is coupled to the lower end of the support shaft 386. The driver 388 rotates and elevates the support shaft 386. The nozzle support 382 is vertically coupled with the opposite end of the support shaft 386 coupled with the driver 388. The nozzle 384 is installed on the bottom end surface of the nozzle support 382. The nozzle 384 is moved to the process position and the standby position by the driver 388. The process position is the position where the nozzle 384 is disposed at the vertical top of the cup 320, and the standby position is the position where the nozzle 384 is off the vertical top of the cup 320.

Each liquid ejecting unit 380 of the first substrate processing apparatus 3100 and the second substrate processing apparatus 3200 may be supplied with liquid from one liquid storage tank 400. The liquid storage tank 400 is connected to the first supply line 410 connected to the liquid discharge unit 380 of the first substrate processing apparatus 3100 and the liquid discharge unit 380 of the second substrate processing apparatus 3200. Is connected to the second supply line 420.

An on-off valve may be provided in each of the first supply line 410 and the second supply line 420. The same processing liquid is provided to the first substrate processing apparatus 3100 and the second substrate processing apparatus 3200. The treatment liquid is provided in the same state. For example, the processing liquid supplied to the first substrate processing apparatus 3100 and the second substrate processing apparatus 3200 may be provided with the same temperature, concentration, and flow rate.

3 is a plan view schematically showing the first substrate processing apparatus 3100 of FIG. 2 and the support unit 340 of the second substrate processing apparatus 3200, and FIG. 4 is the first substrate processing apparatus 3100 of FIG. 2. And a second substrate processing apparatus 3200. The support unit 340 of the first substrate processing apparatus 3100 and the second substrate processing apparatus 3200 will be described simultaneously with reference to FIGS. 3 and 4.

3 and 4, the support unit 340 supports the substrate W during the process and rotates the substrate W. The support unit 340 has a support plate 342, a support pin 344, a chuck pin 346, a chuck pin moving unit 347, and a rotating shaft 348.

The support plate 342 has an upper surface provided in a substantially circular shape when viewed from the top. The support pin 344 protrudes upward from the upper surface of the support plate 342 in the edge region of the support plate 342. The support pin 344 is spaced a predetermined distance along the circumference of the support plate 342 to support the bottom edge of the substrate W. The support pins 344 all have the same shape and size. The support pin 344 has an upper portion 344a, which gradually increases in diameter as it goes down, and a lower portion 344b, which extends downward therefrom and has the same diameter. The bottom surface of the lower portion 344b of the support pin 344 is provided with a cylindrical protrusion 344c extending in the longitudinal direction of the support pin 344. The diameter of the protruding portion 344c is provided smaller than the diameter of the lower portion 344b of the support pin 344. The outer surface of the support pin 344 is coated with a conductive material. For example, the conductive material may be ceramics having conductivity.

The chuck pin 346 protrudes upward from the upper surface of the support plate 342 in the edge region of the support plate 342. The chuck pin 346 is positioned at a predetermined distance apart along the circumference of the support plate 342. In addition, the chuck pin 346 is disposed farther than the support pin 344 from the center of the support plate 342. The chuck pin 346 supports the side of the substrate W so that the substrate W does not deviate laterally from the fixed position when the substrate W is rotated. The chuck pins 346 all have the same shape and size. The chuck pin 346 has a support portion 346a, a central portion 346c, a fastening portion 346e, and a locking portion 346d. The support portion 346a has a shape in which the diameter gradually decreases as it goes down from the flat upper surface and then increases in diameter gradually as it goes down again. Therefore, the support portion 346a has a concave portion 346b that is concave inward when viewed from the front. The concave portion 346b contacts the side of the substrate W placed on the support pin 344. The central portion 346c extends downward from the lower end of the support portion 346a with this same diameter. The fastening portion 346e extends downward from the central portion 346c. A screw hole for fastening with the chuck pin moving unit 347 to be described later is formed in the fastening portion 346e. The engaging portion 346d extends outwardly from the central portion 346c and is provided in a ring shape. The engaging portion 346d is in close contact with the upper surface of the support plate 342, so that the chuck pins 346 all protrude to the same height.

The chuck pin 346 of the first substrate processing apparatus 3100 is provided as the first chuck pin 1346, and the chuck pin 346 of the second substrate processing apparatus 3200 is provided as the second chuck pin 2346 do. The first chuck pin 1346 and the second chuck pin 2346 are provided with different materials. The structures of the first chuck pin 1346 and the second chuck pin 2346 are provided identically. The first chuck pin 1346 is provided from material A, and the second chuck pin 2346 is provided from material B. In one embodiment, material A is a material having a lower electrical conductivity than material B. The material of the first chuck pin 1346 and the second chuck pin 2346 may be materials having corrosion resistance, fire resistance, and heat resistance, such as SIC ceramics, CARBON PFA, and CARBON PEEK. In one embodiment, the electrical conductivity of the material containing carbon may be provided differently depending on the carbon content.

The chuck pin moving unit 347 moves the chuck pin 346 to a support position and a standby position. The support position is a position where the chuck pins 346 contact the side of the substrate W during the process, and the standby position provides a larger space than the substrate W so that the substrate W can be placed on the support unit 340 It is a location to do. Therefore, the support position is a position closer to the center of the support plate 342 than the standby position. The chuck pin moving unit 347 includes a moving rod 347a coupled with one chuck pin 346, and the moving rod 347a is disposed in the supporting plate 342 in the same direction as the radial direction of the supporting plate 342 do. The chuck pin 346 and the moving rod 347a may be screwed.

The rotating shaft 348 is fixedly coupled to the bottom surface of the support plate 342 to support the support plate 342 and rotate the support plate 342. The rotating shaft 348 is provided in a hollow cylindrical shape. The rotating shaft 348 protrudes to the outside of the cup 320 through an opening formed in the bottom surface of the cup 320. The lower end of the rotating shaft 348 protruding to the outside is fixedly coupled to the motor 349. The motor 349 provides a rotational force to the rotating shaft 348, whereby the rotating shaft 348 is rotatable.

The ground wire 345 is connected to the chuck pin 346. The chuck pin 346 discharges charges charged to the substrate W or the processing liquid L through the ground wire 345 to the outside. The ground wire 345 is made of a conductive material. The ground wire 345 may be provided inside the moving rod 347a. The ground wire 345 may be connected to the motor power connector ground pin 349a. Due to this, charges charged on the substrate W are discharged to the outside through the chuck pin 346, the ground wire 345, and the motor power connector ground pin 349a.

The support pin ground member 350 discharges the charge charged to the substrate W through the support pin 344 to the outside. The support pin grounding member 350 includes a spring 350a and a rod 350b. The spring 350a and the rod 350b are made of metal. The rod 350b is provided in the radial direction of the support plate 342. One end of the spring 350a is connected to the support pin 344, and the other end thereof is connected to the rod 350b. The rod 350b may be connected to a motor power connector ground pin 349a through a cable. Due to this, the electric charge charged on the substrate W is discharged to the outside through the support pin 344, the spring 350a, the rod 350b, and the motor power connector ground pin 349a. Unlike the above, the spring 350a may have a hollow cylindrical shape surrounding the support pin 344. Due to this, the spring 350a maximizes a surface in contact with the support pin 344 to discharge charges charged to the substrate W more efficiently. In addition, the rod 350b may be directly connected to the support pin 344 without the spring 350a to discharge the charge charged on the substrate W to the outside.

In one embodiment, by changing the material of the support pin 344 and the support pin ground member 350 to provide different electrical conductivity, the etch rate may be varied.

In one embodiment, the chuck pin 346 is grounded and the support pin 344 may not be provided with ground.

5 is a view showing a state in which the processing liquid is supplied from the first substrate processing apparatus 3100. 6 is a view showing a state in which the processing liquid is supplied from the second substrate processing apparatus 3200. The temperatures, concentrations, and flow rates of the processing liquids supplied to the illustrated first substrate processing apparatus 3100 and the second substrate processing apparatus 3200 are the same. In addition, the rotational speeds of the support plates 342 of the first substrate processing apparatus 3100 and the second substrate processing apparatus 3200 are the same.

5 and 6, the processing liquid L is applied on the substrate W supported by the chuck pin 346. The chuck pin 346 directly contacts the processing liquid L applied on the substrate. The processing liquid L applied to the substrate W treats the surface of the substrate. The treatment liquid (L) may be SC-1, APM, Dilute HF (DHF), BOE, or the like. In addition to the above-described example, when the processing liquid L is supplied to the surface of the substrate W while the substrate is rotated, and preferably rotated at a high speed, the substrate W and the processing liquid L are It can be any type of chemical that generates friction and causes polarization. In one embodiment, DHF is ionized to generate H ⁺ and F ⁻ to etch SiO ₂ on the substrate surface.

The processing liquid L is brought into contact with the substrate W, causing friction, and a polarization phenomenon. At this time, the movement of electrons between the substrate W and the processing liquid L promotes ionization of the processing liquid L.

Since the first substrate processing apparatus 3100 to which material A is applied to the chuck pin 346 has low electrical conductivity of the chuck pin 1346, the second substrate processing apparatus 3200 to which material B is applied to the chuck pin 346 The number of electrons moving through the grounded chuck pin 1346 is less than the chuck pin 2346 of. That is, the etching source of the processing liquid L in the first substrate processing apparatus 3100 to which the material A is applied is the chuck pin 1346 to which the material A is applied, compared to the second substrate processing apparatus 3200 to which the material B is applied. Increases. Therefore, when the conditions (temperature, concentration, flow rate, and rotation speed of the substrate) related to the processing liquid L are the same, the etching rate in the first substrate processing apparatus 3100 is higher. In other words, it is possible to control the etch rate by adjusting the electrical conductivity of the chuck pin 346. If the electrical conductivity between the chuck pin 346 and ground is high, the etch rate decreases, and when the electrical conductivity between the chuck pin 346 and ground is low, the etch rate increases. Referring to the embodiment, the target etch rate can be achieved in a fixed processing liquid condition by selecting the degree of grounding of the fin member.

7 is a graph showing the difference in etching rate when the chuck pin 346 to which material A and material B are applied is used. The X-axis (horizontal direction) shows the area from the center of the substrate to the edge of the substrate from left to right, and the Y-axis (vertical direction) is the etching amount. When material A and material B were applied, a difference in etching amount of 1 Å (A) was generated. By varying the electrical conductivity from the chuck pin 346 to the ground, it is possible to control the etch amount in Angstrom units.

According to an embodiment, it is possible to provide a chamber providing two or more different etch rates in one installation. In order to control the etching rate, some components for adjusting the temperature, concentration, flow rate, or rotation speed of the substrate may be omitted, and thus, it is possible to expect an increase in equipment efficiency due to a reduction in manufacturing cost and a reduction in footprint. In addition, it is possible to provide a finely converted etch rate in angstrom units for each chamber in a unit facility receiving the same chemical solution.

8 is a cross-sectional view schematically showing the structure of the substrate processing apparatus 3300 according to the second embodiment. In the embodiment of FIG. 8, the cup 320, the support unit 340, the lifting unit 360, and the liquid ejecting unit 380 except for the parts described later are the first substrate processing apparatus 3100 described with reference to FIGS. 4 to 6 ) And the second substrate processing apparatus 3200.

A variable impedance 500 that can vary in capacitance, inductance or resistance is connected to the ground path between the chuck pin 3346 and ground. Variable impedance 500 is set to have different electrical characteristics depending on the process. For example, in order to increase the etch rate in substrate cleaning, the variable impedance 500 is set to have low electrical conductivity. Alternatively, in order to reduce the etch rate in substrate cleaning, the variable impedance 500 is set to have high electrical conductivity. That is, in the substrate cleaning, the variable impedance 500 is set to have a high impedance to increase the etch rate, and the variable impedance 500 is set to have a low impedance to decrease the etch rate.

The variable impedance 500 may be connected to the controller 600. The controller 600 adjusts the impedance of the variable impedance 500 according to the process.

9 and 10 are views showing a state in which the processing liquid is supplied from the substrate processing apparatus 3300. The temperature, concentration, and flow rate of the treatment liquid supplied in FIGS. 9 and 10 are the same. In addition, the rotational speed of the support plate 342 in FIGS. 9 and 10 is also the same. 9 shows that the electrical conductivity of the variable impedance 500 is set to be relatively lower than that of FIG. 10. FIG. 10 is set such that the electrical conductivity is relatively higher than that of FIG. 9 of the variable impedance 500.

9 and 10, the processing liquid L is applied on the substrate W supported by the chuck pin 3346. The chuck pin 3346 directly contacts the processing liquid L applied on the substrate. The processing liquid L applied to the substrate W treats the surface of the substrate. The treatment liquid (L) may be SC-1, APM, Dilute HF (DHF), BOE, or the like. In addition to the above-described example, when the processing liquid L is supplied to the surface of the substrate W while the substrate is rotated, preferably at a high speed, while the processing liquid L is rotated, It can be any type of chemical that generates friction and causes polarization. In one embodiment, DHF is ionized to generate H ⁺ and F ⁻ to etch SiO ₂ on the substrate surface.

The processing liquid L is brought into contact with the substrate W, causing friction, and a polarization phenomenon. At this time, the movement of electrons between the substrate W and the processing liquid L promotes ionization of the processing liquid L.

Since the electrical conductivity is low according to the embodiment shown in FIG. 9, the number of electrons moving through the grounded chuck pin 3346 is less than the embodiment shown in FIG. 10. That is, as the electrical conductivity of the variable impedance 500 is lower, the etching source of the processing liquid L increases. Therefore, when the conditions associated with the processing liquid L (temperature, concentration, flow rate, and rotation speed of the substrate) are the same, the etching rate is higher when the electrical conductivity of the variable impedance 500 is low. In other words, it is possible to adjust the etch rate by adjusting the electrical conductivity of the variable impedance 500. If the electrical conductivity between the chuck pin 3346 and ground is high, the etch rate decreases. When the electrical conductivity between the chuck pin 3346 and ground is low, the etch rate increases.

Although not shown, a finely adjusted etching rate can be achieved by controlling the temperature, concentration, and flow rate of the processing liquid L together with the chuck pin 346 and the rotation speed of the substrate W together.

As an example, the matter in which the processing liquid L is relatively negatively charged and electrons move from the processing liquid L to ground is illustrated, but the substrate W is relatively charged with negative charge, and the substrate W is grounded. Electrons can be moved.

Although not shown, the object of the present invention is provided by setting and adjusting the electrical conductivity of the conductive member so that a conductive member in contact with the processing liquid is provided on behalf of the chuck pin, the conductive member is grounded, and the substrate processing apparatus provides a set etch rate. It can also be achieved.

1: substrate processing equipment, 10: index module,
20: process processing module, 120: load port,
140: transfer frame, 220: buffer unit,
240: transfer chamber, 260: process chamber,
3100, 3200, 3300: substrate processing equipment,
320: cup, 340: support unit,
346, 1346, 2346, 3346: chuck pin, 380: injection member.

Claims (18)

In the apparatus for processing a substrate,
A first processing unit for liquid-processing the substrate;
A second processing unit for liquid processing the substrate,
The first processing unit and the second processing unit, respectively,
A cup having a processing space therein;
A support unit supporting a substrate in the processing space and including a rotatable support plate;
A liquid discharging unit for discharging a treatment liquid to the substrate supported on the support unit; And
A conductive member directly contacting at least one of the processing liquid supplied on the substrate or the substrate;
The conductive member is provided to be grounded,
The conductive member grounded in the first processing unit and the conductive member grounded in the second processing unit are provided with different electrical conductivity. According to claim 1,
The support unit,
It includes a plurality of pin members provided on the support plate to support the substrate located on the upper surface of the support plate,
The conductive member is a substrate processing apparatus provided as one or more of the pin member. According to claim 1,
The substrate processing apparatus, wherein the conductive member grounded in the first processing unit and the conductive member grounded in the second processing unit are chuck pins supporting side surfaces of the substrate. The method according to any one of claims 1 to 3,
The first processing unit and the second processing unit are substrate processing apparatus provided to perform the same process. The method according to any one of claims 1 to 3,
The processing liquid supplied by the liquid discharge unit provided to each of the first processing unit and the second processing unit is a chemical that is ionized and reacts with a substrate. Etching the substrate by supplying a processing liquid to the substrate is located in the processing chamber is rotated,
While the processing liquid is supplied to the substrate, the processing liquid supplied on the substrate or the substrate is in contact with a grounded pin member,
A control method of the etching rate of the substrate, the substrate processing method comprising the electrical conductivity of the fin member. The method of claim 6,
The pin member is a substrate processing method of at least one of a plurality of pin members for supporting the substrate. The method of claim 6,
A method for processing a substrate by increasing the electrical conductivity of the grounded fin member to reduce the etch rate. The method of claim 6,
A pin member having an electrical conductivity of the first size is used when the etching rate of the substrate is to be the first etching rate, and a pin having an electrical conductivity of the second size when the etching rate of the substrate is to be the second etching rate. Use absence,
The first etch rate is greater than the second etch rate, the first size is less than the second size of the substrate processing method. The method according to any one of claims 6 to 9,
More than one processing chamber is provided,
The conductive member provided in one of the processing chambers is provided with a higher or lower electrical conductivity than the conductive member provided in the other one of the processing chambers. The method according to any one of claims 6 to 9,
The processing liquid supplied by the liquid ejecting unit is a chemical treatment that is ionized and reacts with the substrate. The method according to any one of claims 6 to 9,
The processing liquid is a substrate processing method comprising hydrofluoric acid. In the apparatus for processing a substrate,
It includes a liquid processing unit for liquid processing the substrate,
The liquid processing unit,
A cup having a processing space therein;
A support unit supporting a substrate in the processing space and including a rotatable support plate;
A liquid discharging unit for discharging a treatment liquid to the substrate supported on the support unit;
And a conductive member in direct contact with at least one of the processing liquid supplied on the substrate or the substrate,
The conductive member is provided to be grounded,
A substrate processing apparatus in which a variable impedance is installed in a ground path provided between the grounded conductive member and the ground. The method of claim 13,
The variable impedance is a substrate processing apparatus provided as one or more of a variable resistor, a variable capacitor or a variable inductor. The method of claim 13,
Further comprising a controller for controlling the variable impedance,
The controller is a substrate processing apparatus that increases the impedance when it is desired to increase the etching rate. The method of claim 13,
Further comprising a controller for controlling the variable impedance,
The controller is a substrate processing apparatus for adjusting the impedance of the variable impedance according to the process. The method according to any one of claims 13 to 16,
The support unit,
It includes a plurality of pin members provided on the support plate to support the substrate located on the upper surface of the support plate,
The conductive member is a substrate processing apparatus provided as one or more of the pin member. The method according to any one of claims 13 to 16,
The processing liquid supplied by the liquid discharging unit is a chemical treatment that is ionized and reacts with the substrate.

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