JP2023029455A - Substrate processing apparatus, substrate processing method, and computer-readable recording medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a substrate processing apparatus, a substrate processing method, and a computer-readable recording medium capable of supplying ozone water with a stable ozone concentration to a substrate.

SOLUTION: A substrate processing apparatus includes an ozone gas supply unit configured to supply ozone gas, an adjustment liquid supply unit configured to supply an adjustment liquid exhibiting a predetermined hydrogen ion concentration, a dissolving unit configured to dissolve ozone gas in an adjustment liquid to generate ozone water, at least one processing chamber configured to clean a substrate with ozonated water, and a liquid feed unit configured to feed ozone water from the dissolving unit to at least one processing chamber through a liquid feed line.

SELECTED DRAWING: Figure 2

COPYRIGHT: (C)2023,JPO&INPIT

Description

The present disclosure relates to substrate processing apparatuses, substrate processing methods, and computer-readable recording media.

Patent Literature 1 discloses a substrate processing apparatus that removes deposits (eg, resist film, contaminants, oxide film, etc.) adhering to a substrate by supplying high-concentration ozone water to the substrate.

JP 2008-311256 A

It is known that the ozone concentration of high-concentration ozonated water attenuates in a short time. Accordingly, the present disclosure describes a substrate processing apparatus, a substrate processing method, and a computer-readable recording medium capable of supplying ozone water with a stable ozone concentration to a substrate.

An example of a substrate processing apparatus includes an ozone gas supply unit configured to supply ozone gas, an adjustment liquid supply unit configured to supply adjustment liquid exhibiting a predetermined hydrogen ion concentration, and an ozone gas dissolved in the adjustment liquid. at least one processing chamber configured to perform a cleaning process on the substrate with the ozone water; and the at least one treatment of the ozone water from the dissolution unit through the liquid feed line. a liquid delivery section configured to deliver liquid to the chamber.

According to the substrate processing apparatus, the substrate processing method, and the computer-readable recording medium according to the present disclosure, it is possible to supply ozone water with a stable ozone concentration to the substrate.

FIG. 1 is a plan view schematically showing an example of a substrate processing system. FIG. 2 is a diagram showing an example of a substrate processing apparatus. FIG. 3 is a block diagram showing an example of main parts of the substrate processing system. FIG. 4 is a schematic diagram showing an example of the hardware configuration of the controller. FIG. 5 is a flow chart for explaining the wafer processing steps. FIG. 6 is a diagram showing another example of the substrate processing apparatus.

An example of an embodiment according to the present disclosure will be described below in more detail with reference to the drawings. In the following description, the same reference numerals will be used for the same elements or elements having the same functions, and redundant description will be omitted.

[Configuration of substrate processing system]
FIG. 1 is a diagram showing a schematic configuration of a substrate processing system according to this embodiment. Hereinafter, in order to clarify the positional relationship, the X-axis, Y-axis and Z-axis are defined to be orthogonal to each other, and the positive direction of the Z-axis is defined as the vertically upward direction.

As shown in FIG. 1, the substrate processing system 1 includes a loading/unloading station 2 and a processing station 3 . The loading/unloading station 2 and the processing station 3 are provided adjacently.

The loading/unloading station 2 includes a carrier placement section 11 and a transport section 12 . A plurality of carriers C for accommodating a plurality of substrates, in this embodiment, semiconductor wafers (hereinafter referred to as wafers W) in a horizontal state are mounted on the carrier mounting portion 11 .

The transfer section 12 is provided adjacent to the carrier mounting section 11 and includes a substrate transfer device 13 and a transfer section 14 therein. The substrate transfer device 13 includes a wafer holding mechanism that holds the wafer W. As shown in FIG. In addition, the substrate transfer device 13 can move in the horizontal direction and the vertical direction and can rotate around the vertical axis, and transfers the wafer W between the carrier C and the transfer section 14 using the wafer holding mechanism. conduct.

The processing station 3 is provided adjacent to the transport section 12 . The processing station 3 comprises a transport section 15 and a plurality of processing units 16 . A plurality of processing units 16 are arranged side by side on both sides of the transport section 15 .

The transport unit 15 includes a substrate transport device 17 inside. The substrate transfer device 17 has a wafer holding mechanism for holding the wafer W. As shown in FIG. In addition, the substrate transfer device 17 can move in the horizontal direction and the vertical direction and can rotate about the vertical axis, and transfers the wafer W between the transfer section 14 and the processing unit 16 using the wafer holding mechanism. I do.

The processing unit 16 performs predetermined substrate processing on the wafer W transferred by the substrate transfer device 17 .

The substrate processing system 1 also includes a control device 4 . Control device 4 is, for example, a computer, and includes control unit 18 and storage unit 19 . The storage unit 19 stores programs for controlling various processes executed in the substrate processing system 1 . The control unit 18 controls the operation of the substrate processing system 1 by reading and executing programs stored in the storage unit 19 .

The program may be recorded in a computer-readable storage medium and installed in the storage unit 19 of the control device 4 from the storage medium. Examples of computer-readable storage media include hard disks (HD), flexible disks (FD), compact disks (CD), magnet optical disks (MO), and memory cards.

In the substrate processing system 1 configured as described above, first, the substrate transfer device 13 of the loading/unloading station 2 takes out the wafer W from the carrier C placed on the carrier platform 11, and receives the taken out wafer W. It is placed on the transfer section 14 . The wafer W placed on the transfer section 14 is taken out from the transfer section 14 by the substrate transfer device 17 of the processing station 3 and carried into the processing unit 16 .

The wafer W loaded into the processing unit 16 is processed by the processing unit 16 , then unloaded from the processing unit 16 by the substrate transfer device 17 and placed on the delivery section 14 . Then, the processed wafer W placed on the transfer section 14 is returned to the carrier C on the carrier placement section 11 by the substrate transfer device 13 .

[Configuration of substrate processing apparatus]
Next, the configuration of the substrate processing apparatus 10 included in the substrate processing system 1 will be described with reference to FIGS. 2 to 4. FIG. The substrate processing apparatus 10 has a function of supplying ozone water to the wafer W to remove deposits adhering to the surface of the wafer W. FIG.

The wafer W may have a disk shape, or may have a plate shape such as a polygonal shape other than a circular shape. The wafer W may have a cutout portion that is partially cut out. The notch may be, for example, a notch (a U-shaped, V-shaped groove, etc.) or a linear portion extending linearly (so-called orientation flat). The wafer W may be, for example, a semiconductor substrate, a glass substrate, a mask substrate, an FPD (Flat Panel Display) substrate, or other various substrates. The diameter of the wafer W may be, for example, approximately 200 mm to 450 mm.

As shown in FIG. 2, the substrate processing apparatus 10 includes a plurality of processing units 16, an ozone water supply section 100, an alkaline solution supply section 200, a rinse liquid supply section 300, a liquid discharge section 400, and an exhaust section. 500 and a control device 4 (control unit 18).

[Processing unit]
The processing unit 16 includes a processing chamber 16a, a spin holder 16b, and nozzles N1 and N2. The processing chamber 16a is configured such that the wafer W can be taken in and out through a gate valve (not shown). The rotary holding part 16b is configured to hold and rotate the wafer W, and is arranged in the processing chamber 16a.

The nozzles N1 and N2 are arranged in the processing chamber 16a so as to be positioned above the wafer W while the wafer W is held by the spin holder 16b. Ozone water is discharged from the nozzle N1. A rinse liquid is discharged from the nozzle N2. Although FIG. 2 illustrates three processing units 16 (16A to 16C) arranged side by side, the number of processing units 16 is not particularly limited. That is, the substrate processing apparatus 10 may have at least one processing unit 16 .

[Ozonated water supply unit]
The ozone water supply unit 100 has a function of generating ozone water and a function of supplying the generated ozone water to the wafer W through the nozzle N1. The ozone water supply unit 100 includes an ozone gas supply unit 110 , a conditioning liquid supply unit 120 , a dissolution unit 130 , and a liquid supply unit 140 .

The ozone gas supply unit 110 is configured to generate ozone gas from oxygen. The ozone gas supply unit 110 is connected to the dissolving unit 130 via the pipe D1 and supplies the generated ozone gas to the dissolving unit 130 . The adjustment liquid supply unit 120 includes liquid sources 121 and 122, a circulation tank 123, a pump 124, a heater 125, a hydrogen ion concentration monitor 126, and valves V1 to V3.

The liquid source 121 is configured to store an acidic solution. The acidic solution may be a solution of an organic acid (eg, citric acid, acetic acid, carbonic acid), a solution of an inorganic acid (eg, hydrochloric acid, nitric acid), or a mixture of an organic acid and an inorganic acid. It may be a mixed solution. When using an acidic solution in which an organic acid and an inorganic acid (for example, hydrochloric acid) are mixed, the solubility of the resist can be enhanced. The liquid source 121 is connected to the circulation tank 123 via the pipe D2 and supplies the acid solution to the circulation tank 123 .

The liquid source 122 is configured to store water (eg, pure water, DIW (Deionized Water)). The liquid source 122 is connected to the circulation tank 123 through the pipes D2 and D3 and supplies water to the circulation tank 123 . The pipe D3 may be connected to the middle of the pipe D2. In this case, the acidic solution and water are mixed at the confluence of the pipes D2 and D3 to generate the adjustment liquid. The adjustment liquid is adjusted to exhibit a predetermined hydrogen ion concentration. The hydrogen ion concentration of the adjustment liquid may be adjusted, for example, based on the flow rate and concentration of the acidic solution supplied from the liquid source 121 and the flow rate of water supplied from the liquid source 122 . The hydrogen ion concentration of the adjustment liquid may be, for example, about pH 1 to pH 4.

The circulation tank 123 is configured to temporarily store the adjustment liquid and circulate the adjustment liquid through the pipe D4. By circulating the adjustment liquid through the circulation tank 123 and the pipe D4, the water and the acid solution can be sufficiently uniformly mixed in the process of circulation.

A pipe D4 connects the lower part and the upper part of the circulation tank 123 . A pump 124, a heater 125, a hydrogen ion concentration monitor 126, and a valve V3 are connected to the pipe D4 in this order from the upstream side. The pump 124 is configured to operate based on a control signal from the control device 4 and feed the adjustment liquid in the circulation tank 123 downstream through the pipe D4. The heater 125 is configured to operate based on a control signal from the control device 4 and heat the adjustment liquid so that the adjustment liquid reaches a predetermined temperature (for example, about 22° C. to 85° C.).

The hydrogen ion concentration monitor 126 is configured to acquire hydrogen ion concentration data of the adjustment liquid flowing through the pipe D4. Data acquired by the hydrogen ion concentration monitor 126 is transmitted to the control device 4 .

The valves V1 to V3 are provided midway along the pipes D2 to D4, respectively. The valve V1 is configured to operate based on a control signal from the control device 4 and control the flow rate of the acidic solution flowing through the pipe D2. The valve V2 is configured to operate based on a control signal from the control device 4 and control the flow rate of water flowing through the pipe D3.

The valve V3 is operated based on a control signal from the control device 4, and has a channel through which the adjustment liquid circulates through the pipe D4 and the circulation tank 123, and the adjustment liquid is sent from the circulation tank 123 to the dissolving section 130 through the pipes D4 and D5. It is configured to be switchable between the flow path in which the liquid is supplied. Valve V3 may be, for example, a three-way electromagnetic valve (solenoid valve). A pipe D5 connects the valve V3 and the dissolving section 130 .

The dissolving unit 130 is configured to dissolve the ozone gas supplied from the ozone gas supply unit 110 in the adjustment liquid supplied from the adjustment liquid supply unit 120 to generate ozone water. The dissolution unit 130 is, for example, a dissolution module that causes ozone gas to flow on the primary side of the porous membrane and water to flow on the secondary side of the porous membrane to bring the gas and liquid into contact and dissolve the ozone gas in water. good too.

The liquid sending unit 140 has a function of sending the ozone water generated in the dissolving unit 130 to each of the processing units 16A to 16C or the liquid draining unit 400 . The liquid feeding unit 140 includes pipes D6 to D9 (liquid feeding lines), an auxiliary heater 141, a temperature monitor 142, an ozone concentration monitor 143, and valves V4 to V6.

The pipe D6 extends to connect the dissolving section 130 and the drain section 400 . An auxiliary heater 141, a temperature monitor 142, and an ozone concentration monitor 143 are connected to the pipe D6 in this order from the upstream side. The auxiliary heater 141 operates based on a control signal from the control device 4 and is configured to heat the ozonated water to a predetermined temperature (for example, about 22° C. to 85° C.). The temperature monitor 142 is configured to acquire temperature data of the ozone water flowing through the pipe D6. Data acquired by the temperature monitor 142 is transmitted to the controller 4 .

The ozone concentration monitor 143 is configured to acquire data on the ozone concentration of the ozone water flowing through the pipe D6. That is, the ozone concentration monitor 143 acquires data on the ozone concentration of the ozonized water on the downstream side of the dissolving section 130 . Data acquired by the ozone concentration monitor 143 is transmitted to the control device 4 . The ozone concentration monitor 143 is set at a position where the path length from the dissolving section 130 to the ozone concentration monitor 143 and each path length from the dissolving section 130 to each processing unit 16A to 16C (to each nozzle N1) are substantially equal. may be

The pipes D7 to D9 branch off from the middle of the pipe D6 and are connected to the nozzles N1 of the respective processing units 16A to 16C. The pipes D7 and D8 may respectively include adjusting portions D7a and D8a for ensuring predetermined path lengths. The adjustment portions D7a and D8a may be, for example, the pipes D7 and D8 that partially meander, or the pipes D7 and D8 that partially extend spirally. Due to the existence of these adjusting sections D7a and D8a, the path lengths from the dissolving section 130 to the processing units 16A to 16C (to the nozzles N1) may be substantially the same. Note that the pipe D9 may also include an adjustment section.

The valves V4 to V6 are provided in the middle of the pipes D7 to D9, respectively. The valves V4 to V6 are configured to operate based on control signals from the control device 4, and to mix the ozone water flowing through the pipes D7 to D9 with the alkaline adjustment liquid supplied from the alkaline solution supply unit 200. Valves V4-V6 may be, for example, mixing faucets.

[Alkaline solution supply part]
The alkaline solution supply unit 200 has a function of generating an alkali adjusting solution and a function of supplying the generated alkali adjusting solution to the wafer W through the nozzle N1. The alkaline solution supply unit 200 includes liquid sources 201 and 202, a circulation tank 203, a pump 204, a heater 205, a hydrogen ion concentration monitor 206, and valves V7 and V8.

The liquid source 201 is configured to store an alkaline solution. The alkaline solution may be, for example, aqueous ammonia. The liquid source 201 is connected to the circulation tank 203 via the pipe D10, and supplies the alkaline solution to the circulation tank 203.

Like the liquid source 122, the liquid source 202 is configured to store water (for example, pure water, DIW (Deionized Water)). The liquid source 202 is connected to the circulation tank 203 via pipes D10 and D11 and supplies water to the circulation tank 203 . The pipe D11 may be connected to the middle of the pipe D10. In this case, the alkaline solution and water are mixed at the confluence portion of the pipes D10 and D11 to generate the alkali adjusting solution. The alkali-adjusting liquid is adjusted so as to exhibit a predetermined hydrogen ion concentration. The hydrogen ion concentration of the adjustment liquid may be adjusted, for example, based on the flow rate and concentration of the alkaline solution supplied from the liquid source 201 and the flow rate of water supplied from the liquid source 122 . The hydrogen ion concentration of the alkali adjusting liquid may be, for example, about pH9 to pH13.

The circulation tank 203 is configured to temporarily store the alkali adjusting liquid and circulate the alkali adjusting liquid through the pipe D12. By circulating the alkali-adjusting liquid through the circulation tank 203 and the pipe D12, the water and the alkaline solution can be sufficiently uniformly mixed in the process of circulation.

A pipe D<b>12 connects the lower part and the upper part of the circulation tank 203 . A pump 204, a heater 205, and a hydrogen ion concentration monitor 206 are connected to the pipe D12 in this order from the upstream side. The pump 204 is configured to operate based on a control signal from the control device 4 and feed the adjustment liquid in the circulation tank 203 downstream through the pipe D12. The heater 205 is configured to operate based on a control signal from the control device 4 and heat the alkali adjusting liquid so that the alkali adjusting liquid reaches a predetermined temperature (for example, about 22° C. to 85° C.).

The hydrogen ion concentration monitor 206 is configured to acquire hydrogen ion concentration data of the alkali adjusting liquid flowing through the pipe D12. Data acquired by the hydrogen ion concentration monitor 206 is transmitted to the control device 4 .

The pipe D12 is connected to pipes D13 to D15 branched from the middle thereof. A pipe D13 branched from the pipe D12 is connected to a valve V4. A pipe D14 branched from the pipe D12 on the downstream side of the pipe D13 is connected to the valve V5. A pipe D15 branched from the pipe D12 on the downstream side of the pipe D14 is connected to the valve V6. Therefore, the alkaline adjustment liquid supplied from the alkaline solution supply unit 200 is mixed with the ozonized water supplied from the ozonized water supply unit 100 at the valves V4 to V6.

Valves V7 and V8 are provided in the middle of pipes D10 and D11, respectively. The valve V7 is configured to operate based on a control signal from the control device 4 and control the flow rate of the alkaline solution flowing through the pipe D10. The valve V8 is configured to operate based on a control signal from the control device 4 and control the flow rate of water flowing through the pipe D11.

[Rinse liquid supply unit]
The rinse liquid supply unit 300 has a function of supplying the rinse liquid to the wafer W through the nozzle N2. The rinse liquid supply unit 300 includes a liquid source 301, a pump 302, and valves V9 to V11. The liquid source 301 is configured to store the rinse liquid. The rinsing liquid is used to wash away, for example, chemical liquids and substances adhering to the substrate. The rinse liquid may be water (eg, pure water, DIW (Deionized Water)). The liquid source 301 extends toward each of the processing units 16A-16C via pipes D16-D19. The pipes D17 to D19 branch off from the middle of the pipe D16 and are connected to the nozzles N2 of the processing units 16A to 16C. Therefore, the rinse liquid supplied from the liquid source 301 is supplied to the nozzles N2 of the processing units 16A to 16C.

The pump 302 is provided in the middle of the pipe D16. The pump 302 is configured to operate based on a control signal from the control device 4 and feed the rinse liquid downstream through the pipe D16. The valves V9 to V11 are provided midway along the pipes D17 to D19, respectively. The valves V9 to V11 are configured to operate based on control signals from the control device 4, respectively, and control the flow rate of the rinse liquid flowing through the pipes D17 to D19.

[Drainage part]
The drainage section 400 includes a drainage treatment unit 401 and a valve V12. The waste liquid treatment unit 401 is configured to decompose ozone contained in ozone water into oxygen. For decomposition of ozone, for example, an ozone decomposition catalyst, activated carbon, or the like may be used. The waste liquid processing unit 401 is connected to the dissolving section 130 via a pipe D6. Therefore, the ozonized water generated in the ozonized water supply unit 100 but not supplied to the nozzle N1 flows into the waste liquid treatment unit 401 through the pipe D6. The valve V12 is provided in the middle of the pipe D6. The valve V12 is configured to operate based on a control signal from the control device 4 and control the flow rate of the ozone water flowing through the pipe D16.

The waste liquid processing unit 401 is connected to each of the processing units 16A to 16C by a pipe D20 branched into three. Therefore, the ozone water used for cleaning the wafer W in each of the processing units 16A to 16C flows into the waste liquid processing unit 401 through the pipe D20. The liquid treated by the waste liquid treatment unit 401 is discharged outside the system.

[Exhaust part]
The exhaust section 500 includes an exhaust processing unit 501 and a pump 502 . The exhaust treatment unit 501 is configured to decompose ozone gas into oxygen. For decomposition of ozone, for example, an ozone decomposition catalyst, activated carbon, or the like may be used. The exhaust processing unit 501 is connected to each of the processing units 16A to 16C by three branched pipes D21. Therefore, the ozone gas generated inside during the cleaning process in each of the processing units 16A to 16C flows into the exhaust processing unit 501 through the pipe D21. The gas treated by the exhaust treatment unit 501 is discharged outside the system.

The pump 502 is provided in the middle of the pipe D21. The pump 502 is configured to operate based on a control signal from the control device 4 and feed the ozone gas downstream through the pipe D21.

[Control device]
As shown in FIG. 3, for example, the control device 4 has a functional configuration (functional modules) for controlling the substrate processing apparatus 10, including a hydrogen ion concentration control section M1, a liquid transfer control section M2, and a liquid discharge control section M2. It includes a controller M3 and an exhaust controller M4. These functional modules are configured by cooperation of the control section 18 and the storage section 19 of the control device 4 . The storage unit 19 stores, for example, programs read from the recording medium RM, various data (so-called processing recipes) for processing the wafer W, and setting data input by an operator via an external input device (not shown). etc. may be stored.

The hydrogen ion concentration control unit M1 controls the adjustment liquid supply unit 120 so as to adjust the hydrogen ion concentration of the adjustment liquid generated in the adjustment liquid supply unit 120 according to the ozone concentration acquired by the ozone concentration monitor 143. may Incidentally, it is known that the higher the concentration of hydrogen ions in the adjustment liquid (the lower the pH), the easier it is for ozone gas to dissolve in the adjustment liquid. Therefore, for example, when the ozone concentration acquired by the ozone concentration monitor 143 is lower than a predetermined value, the hydrogen ion concentration control unit M1 instructs the valves V1 and V2 to change the supply amount of the acidic solution from the liquid source 121 to and/or reducing the amount of water supplied from the liquid source 122 . For example, when the ozone concentration acquired by the ozone concentration monitor 143 is higher than a predetermined value, the hydrogen ion concentration control unit M1 instructs the valves V1 and V2 to reduce the supply amount of the acidic solution from the liquid source 121. and/or increasing the supply of water from the liquid source 122 .

The hydrogen ion concentration control unit M1 controls the alkaline solution supply unit 200 so as to adjust the hydrogen ion concentration of the alkali adjustment liquid generated in the alkaline solution supply unit 200 according to the hydrogen ion concentration acquired by the hydrogen ion concentration monitor 206. may be controlled. For example, when the hydrogen ion concentration acquired by the ozone concentration monitor 143 is higher than a predetermined value, the hydrogen ion concentration control unit M1 instructs the valves V7 and V8 to reduce the supply amount of the alkaline solution from the liquid source 201. At least one of increasing and decreasing the supply of water from the liquid source 202 may be performed. For example, when the hydrogen ion concentration acquired by the hydrogen ion concentration monitor 206 is lower than a predetermined value, the hydrogen ion concentration control unit M1 instructs the valves V7 and V8 to control the supply amount of the alkaline solution from the liquid source 201. and/or increasing the supply of water from the liquid source 202 may be performed.

The liquid transfer controller M2 may control the pump 124 and the valve V3 so as to switch between circulation of the adjustment liquid through the circulation tank 123 and the pipe D4 and supply of the adjustment liquid to the dissolving section . The liquid sending control unit M2 determines that the temperature obtained by the temperature monitor 142 is equal to or higher than a predetermined value, the hydrogen ion concentration obtained by the hydrogen ion concentration monitors 126 and 206 is equal to or higher than a predetermined value, and the ozone concentration monitor 143 obtains The pump 124 and the valves V3 to V6 may be controlled so that the ozone water generated in the dissolving section 130 is sent to at least one of the processing units 16A to 16C when the ozone concentration is equal to or higher than a predetermined value. . At this time, the liquid supply controller M2 may control the valves V3 to V6 so that the alkaline adjustment liquid generated in the alkaline solution supply section 200 is mixed with the ozone water. The liquid feed controller M2 controls the valves V3 to V6 so as not to feed the ozonized water to the rest of the processing units 16A to 16C when the ozonized water is fed to any one of the processing units 16A to 16C. may be controlled. The liquid transfer controller M2 may control the valves V9 to V11 so as to transfer the rinse liquid from the liquid source 301 to at least one of the processing units 16A to 16C.

The liquid discharge controller M3 may control the valve V12 so as to discharge the ozone water to the outside of the system when the ozone water is not sent to at least one of the processing units 16A to 16C. The drainage controller M3 determines that the temperature acquired by the temperature monitor 142 is less than a predetermined value, the hydrogen ion concentration acquired by the hydrogen ion concentration monitors 126 and 206 is less than a predetermined value, or the ozone concentration monitor 143 acquires The valve V12 may be controlled to discharge the ozone water generated in the dissolving section 130 to the outside of the system when the ozone concentration is less than a predetermined value. Alternatively, the liquid discharge controller M3 may control the valve V12 so as to discharge the ozone water to the outside of the system when the ozone water is not sent to any of the processing units 16A to 16C.

The exhaust controller M4 may control the pump 502 so as to suck the gas in the processing units 16A to 16C and exhaust it outside the system.

The hardware of the control device 4 is composed of, for example, one or more control computers. The control device 4 has, for example, a circuit 4A shown in FIG. 4 as a hardware configuration. The circuit 4A may be composed of electrical circuitry. Specifically, the circuit 4A has a processor 4B, a memory 4C (storage section), a storage 4D (storage section), and an input/output port 4E. The processor 4B cooperates with at least one of the memory 4C and the storage 4D to execute a program and input/output signals via the input/output port 4E, thereby configuring each functional module described above. The input/output port 4E performs signal input/output between the processor 4B, the memory 4C, the storage 4D, and each part of the substrate processing apparatus 10. FIG.

The substrate processing apparatus 10 may include, for example, one controller 4 or may include a controller group (control section) composed of a plurality of controllers 4 . When the substrate processing apparatus 10 includes a controller group, each of the above functional modules may be implemented by one control device 4, or may be implemented by a combination of two or more control devices 4. good too. When the control device 4 is composed of a plurality of computers (circuits 4A), each of the above functional modules may be realized by one computer (circuits 4A), or may be realized by two or more computers (circuits 4A). 4A) may be realized by a combination. The controller 4 may have multiple processors 4B. In this case, each of the above functional modules may be implemented by one or more processors 4B.

[Substrate processing method]
Next, a cleaning processing method (substrate processing method) for the wafer W will be described with reference to FIG. First, a preparatory process for cleaning the wafer W is performed (see step S1). In the preparatory process, the liquid transfer control unit M2 and the liquid discharge control unit M3 control the pump 124 and the valve V12 based on data input from the hydrogen ion concentration monitor 126, the temperature monitor 142 and the ozone concentration monitor 143.

For example, the liquid supply control unit M2 and the liquid discharge control unit M3 determine whether or not the data acquired by the temperature monitor 142 and the ozone concentration monitor 143 are both equal to or greater than a predetermined value. As a result, if any of the data acquired by the hydrogen ion concentration monitor 126, the temperature monitor 142, and the ozone concentration monitor 143 is less than the predetermined value, the ozone water is not sent to the processing units 16A to 16C and is discharged outside the system. To discharge the liquid, the liquid supply control section M2 closes the valves V4 to V6, and the liquid discharge control section M3 opens the valve V12.

When the data of the hydrogen ion concentration monitor 126 is less than the predetermined value, the hydrogen ion concentration control section M1 may control the valves V1 and V2 so that the hydrogen ion concentration of the adjustment liquid is equal to or higher than the predetermined value. When the data of the temperature monitor 142 is less than the predetermined value, the control device 4 may control the heater 125 so that the temperature of the adjustment liquid becomes equal to or higher than the predetermined value. When the data of the ozone concentration monitor 143 is less than the predetermined value, the hydrogen ion concentration control section M1 may control the valves V1 and V2 so that the ozone concentration of the ozonized water is equal to or higher than the predetermined value.

On the other hand, when all of the data acquired by the hydrogen ion concentration monitor 126, the temperature monitor 142, and the ozone concentration monitor 143 are equal to or greater than the predetermined value, the liquid supply controller M2 and the liquid discharge controller M3 clean the wafer W. It is determined that preparations for processing are completed (preparation processing completed).

When the preparation process is completed, next, the transfer process of the wafer W is performed (see step S2). For example, the control device 4 controls the substrate transfer devices 13 and 17 so as to transfer one wafer W in the carrier C to the processing unit 16A. As a result, the wafer W is held by the spin holder 16b in the processing unit 16A.

When the transfer process of the wafer W to the processing unit 16A is completed, next, the ozone water supply process to the processing unit 16A is performed (see step S3). For example, the liquid supply controller M2 opens the valve V4 and closes the valves V5 and V6 so as to supply ozone water to the processing unit 16A, and the liquid discharge controller M3 closes the valve V12. As a result, the ozone water is supplied from the nozzle N1 to the wafer W in the processing unit 16A, and the wafer W is cleaned with the ozone water.

In parallel with the process of supplying the ozone water to the processing unit 16A, the transfer process of the wafer W is performed (see step S3). For example, the control device 4 controls the substrate transfer devices 13 and 17 so as to transfer one wafer W in the carrier C to the processing unit 16B. As a result, the wafer W is held by the spin holder 16b in the processing unit 16B.

When the process of supplying the ozone water to the processing unit 16A is completed, next, the process of supplying the rinse liquid to the processing unit 16A is performed (see step S4). For example, the liquid transfer controller M2 opens the valve V9 and closes the valves V10 and V11 so as to transfer the rinse liquid to the processing unit 16A. As a result, the rinse liquid is supplied from the nozzle N2 to the wafer W in the processing unit 16A, and the wafer W is rinsed with the rinse liquid. The rinsed wafers W may be returned into the carrier C by the substrate transfer devices 13 and 17, for example.

In parallel with the process of supplying the rinsing liquid to the processing unit 16A, the process of supplying the ozone water to the processing unit 16B is performed (see step S4). For example, the liquid supply controller M2 opens the valve V5 and closes the valves V4 and V6 so as to supply ozone water to the processing unit 16B, and the liquid discharge controller M3 closes the valve V12. As a result, the ozone water is supplied from the nozzle N1 to the wafer W in the processing unit 16B, and the wafer W is cleaned with the ozone water. The process of supplying ozone water to the processing unit 16B may be performed after the supply of ozone water to the processing unit 16A is stopped, or may be performed after the process of supplying the rinse liquid to the processing unit 16A is started. may be done.

In parallel with the process of supplying the rinse liquid to the processing unit 16A, the transfer process of the wafer W is performed (see step S4). For example, the control device 4 controls the substrate transfer devices 13 and 17 so as to transfer one wafer W in the carrier C to the processing unit 16C. As a result, the wafer W is held by the spin holder 16b in the processing unit 16C.

When the process of supplying the ozone water to the processing unit 16B is completed, the process of supplying the rinsing liquid to the processing unit 16B is next performed (see step S5). For example, the liquid transfer controller M2 opens the valve V10 and closes the valves V9 and V11 so as to transfer the rinse liquid to the processing unit 16B. As a result, the rinse liquid is supplied from the nozzle N2 to the wafer W in the processing unit 16B, and the wafer W is rinsed with the rinse liquid. The rinsed wafers W may be returned into the carrier C by the substrate transfer devices 13 and 17, for example.

In parallel with the process of supplying the rinsing liquid to the processing unit 16B, the process of supplying the ozone water to the processing unit 16C is performed (see step S5). For example, the liquid supply controller M2 opens the valve V6 and closes the valves V4 and V5 so as to supply ozone water to the processing unit 16C, and the liquid discharge controller M3 closes the valve V12. As a result, the ozone water is supplied from the nozzle N1 to the wafer W in the processing unit 16C, and the wafer W is cleaned with the ozone water. Note that the process of supplying ozone water to the processing unit 16C may be performed after the supply of ozone water to the processing unit 16B is stopped, or may be performed after the process of supplying the rinse liquid to the processing unit 16B is started. may be done.

When the process of supplying the ozone water to the processing unit 16C is completed, the process of supplying the rinsing liquid to the processing unit 16C is next performed (see step S6). For example, the liquid transfer controller M2 opens the valve V11 and closes the valves V9 and V10 so as to transfer the rinse liquid to the processing unit 16C. As a result, the rinse liquid is supplied from the nozzle N2 to the wafer W in the processing unit 16C, and the wafer W is rinsed with the rinse liquid. The rinsed wafers W may be returned into the carrier C by the substrate transfer devices 13 and 17, for example.

[Action]
According to the above example, the ozonated water is generated in the dissolving section 130 immediately before the ozonized water is supplied to the treatment unit 16 . Therefore, the ozonated water is supplied to the treatment unit 16 before the ozone concentration of the ozonized water is greatly attenuated. Therefore, it is possible to supply the wafer W with ozone water having a stable ozone concentration.

According to the above example, the hydrogen ion concentration of the adjustment liquid generated in the adjustment liquid supply section 120 is adjusted according to the ozone concentration acquired by the ozone concentration monitor 143 . Therefore, it is possible to keep the ozone concentration of the ozonated water at an appropriate value.

By the way, the ozone concentration of the ozonated water begins to attenuate immediately after the ozonated water is produced in the dissolving section 130 . Therefore, according to the above example, the path length from the dissolving section 130 to the ozone concentration monitor 143 can be substantially the same as the path length from the dissolving section 130 to each of the processing units 16A to 16C. In this case, the ozone concentration monitor 143 can indirectly acquire the ozone concentration of the ozone water when it is supplied to each of the processing units 16A to 16C. Therefore, it is possible to perform the cleaning process of the wafer W with the ozone water with higher accuracy.

According to the above example, the path lengths from the dissolving section 130 to the processing units 16A to 16C can be substantially the same. Therefore, the amount of attenuation of the ozone concentration until the ozone water reaches the processing units 16A to 16C from the dissolving section 130 is approximately the same. Therefore, uniform cleaning results can be obtained regardless of which processing unit 16 is used to clean the wafer W. FIG.

According to the above example, the adjustment liquid supply section is configured to circulate the adjustment liquid. Therefore, the water and the acid solution are sufficiently uniformly mixed in the course of circulation of the adjustment liquid. Therefore, it is possible to stably dissolve the ozone gas in the adjustment liquid in the dissolving section 130 .

According to the above example, the alkaline solution supply unit 200 can supply the alkali adjusting solution to the pipes D7 to D9 through the valves V4 to V6. In this case, an alkaline solution that reduces the solubility of ozone gas in the adjustment liquid is mixed with the ozone water after the ozone water is produced. Therefore, it is possible to remove the deposits adhering to the wafer W with the alkaline component while suppressing the decrease in the ozone concentration of the ozone water.

According to the above example, when all of the data acquired by the hydrogen ion concentration monitor 126, the temperature monitor 142, and the ozone concentration monitor 143 are equal to or greater than a predetermined value, the liquid supply control unit M2 and the liquid discharge control unit M3 The pump 124 and the valves V3-V6 can be controlled so as to send the ozone water generated in the dissolving section 130 to at least one of the processing units 16A-16C. In this case, the ozone concentration of the ozone water supplied to the processing unit 16 is stably maintained at a predetermined value or higher. Therefore, it is possible to obtain a uniform cleaning result.

According to the above example, the process of supplying ozone water to the processing unit 16B is performed after the supply of ozone water into the processing unit 16A is stopped, and the process of supplying ozone water to the processing unit 16C is performed after the process of supplying the ozone water to the processing unit 16B. It can be done after the ozonated water in is stopped. That is, when ozonated water is sent to any one of the processing units 16A to 16C, the ozonized water is not sent to the rest of the processing units 16A to 16C. In this case, the cleaning process of the wafer W with ozone water is not performed simultaneously in each of the processing units 16A to 16C. Therefore, ozone water with a stable ozone concentration is supplied to each processing unit 16A to 16C. Therefore, even if the wafer W is cleaned in any one of the processing units 16A to 16C, a uniform cleaning result can be obtained.

According to the above example, the liquid discharge controller M3 can control the valve V12 so as to discharge the ozone water to the outside of the system when the ozone water is not sent to at least one of the processing units 16A to 16C. In this case, it becomes difficult for the ozonated water to stay in the pipes D6 to D9 (liquid feed lines), so that the ozone concentration of the ozonized water can be further stabilized.

[Modification]
Although the embodiments according to the present disclosure have been described in detail above, various modifications may be made to the above embodiments without departing from the scope and spirit of the claims.

(1) As shown in FIG. 6, the adjustment liquid supply unit 120 does not include the circulation tank 123 and the like, and supplies the adjustment liquid in which the acid solution from the liquid source 121 and the water from the liquid source 122 are mixed. It may be immediately supplied to the dissolving section 130 without being circulated. In this case, the liquid sources 121 and 122 may be connected to the valve V13 via pipes D2 and D3, respectively. A valve V1 may be provided in the pipe D2. The pipe D3 may be provided with a valve V2 and a heater 125 in this order from the upstream side. The valve V13 may be configured to operate based on a control signal from the control device 4 and mix the acidic solution flowing through the pipe D2 and the water flowing through the pipe D3. The valve V13 may be, for example, a mixing faucet (mixing valve).

(2) The dissolving section 130 may be composed of a plurality of dissolving modules connected in series. In this case, the ozone gas that has not been dissolved in the adjustment liquid in the upstream dissolution module can be supplied to the downstream dissolution module and further dissolved in the adjustment liquid. Therefore, it is possible to generate ozone water with a higher ozone concentration. The dissolving section 130 may be formed by connecting a plurality of dissolving modules in parallel. In this case, it is possible to increase the flow rate of the ozonized water generated by the dissolving module.

(3) The higher the temperature of the ozonated water, the higher the reactivity between the ozone and the deposits adhering to the surface of the wafer W, while the ozone dissolved in the ozonized water becomes gas and diffuses. As a result, the ozone concentration of the ozonized water tends to decrease. Therefore, the processing unit 16 may further include a heating source configured to heat the ozone water ejected from the nozzle N1 directly above the wafer W. FIG. In this case, since the temperature of the ozonized water is relatively low until just before it is discharged onto the wafer W, the ozonized water of high concentration can be supplied to the wafer W. FIG. In addition, since the ozone water discharged from the nozzle N1 is heated directly above the wafer W, the reactivity of ozone to the deposits on the wafer W can be enhanced while minimizing the diffusion of ozone gas from the ozone water. can. Therefore, it is possible to remove deposits adhering to the wafer W very effectively.

The heating source may be, for example, a heater that heats the wafer W from the back surface side, or a heating fluid supply mechanism that sprays high-temperature hot water or steam onto the back surface of the wafer W. FIG. In these cases, within the processing unit 16, the wafer W may be sucked and held by the rotation holding portion 16b, or the peripheral edge of the wafer W may be physically held (the wafer W may be held by a so-called mechanical chuck). may be used).

The heating source may be, for example, a heated body that is heated by electromagnetic induction. In this case, the wafer W is supported by the object to be heated in the processing unit 16 .

The heating source may be, for example, a heater configured to rapidly heat the ozone water just before it is supplied to the nozzle N1.

The processing unit 16 may be a batch-type chamber that simultaneously processes a plurality of wafers W in one processing tank. In this case, the heating source may be a heater configured to rapidly heat up the ozone water just before it is supplied to the processing bath.

(4) The processing unit 16 may further include an irradiation section configured to irradiate energy rays such as ultraviolet rays. The controller 4 may control the irradiator so as to irradiate the wafer W with energy rays during the cleaning process of the wafer W with ozone water. In this case, it is possible to more effectively remove the deposits adhering to the surface of the wafer W. FIG.

(5) When the cleaning process of the wafer W is not performed in any of the processing units 16 for the time being (when a predetermined time or more has passed since the cleaning process is completed), the ozone water is discharged through the drain part 400 to the outside of the system, the generation of ozonated water in the ozonized water supply unit 100 may be stopped.

[Example]
Example 1. An example of a substrate processing apparatus includes an ozone gas supply unit configured to supply ozone gas, an adjustment liquid supply unit configured to supply adjustment liquid exhibiting a predetermined hydrogen ion concentration, and an ozone gas dissolved in the adjustment liquid. at least one processing chamber configured to perform a cleaning process on the substrate with the ozone water; and the at least one treatment of the ozone water from the dissolution unit through the liquid feed line. a liquid delivery section configured to deliver liquid to the chamber. In this case, the ozonated water is generated in the dissolving section immediately before the ozonated water is supplied to the processing chamber. Therefore, the ozonated water is supplied to the processing chamber before the ozone concentration of the ozonized water is greatly attenuated. Therefore, it is possible to supply ozone water with a stable ozone concentration to the substrate.

Example 2. The apparatus of Example 1 may further include a drain section connected to the liquid feed line and configured to drain the ozone water out of the system. In this case, the ozonized water can be continuously generated in the dissolving section, and the ozonized water can be discharged from the draining section when the substrate is not washed with the ozonized water. Therefore, it becomes difficult for the ozonated water to stay in the liquid feeding line, so that the ozone concentration of the ozonized water can be further stabilized.

Example 3. The apparatus of Example 1 or Example 2 may further include an ozone concentration monitor provided in the liquid feed line and configured to acquire the ozone concentration of the ozone water downstream of the dissolving section.

Example 4. The apparatus of Example 3 controls the adjustment liquid supply unit so as to adjust the hydrogen ion concentration of the adjustment liquid generated in the adjustment liquid supply unit according to the ozone concentration obtained by the ozone concentration monitor. A part may be further provided. By the way, the higher the hydrogen ion concentration of the adjustment liquid (the lower the pH), the easier the ozone gas dissolves in the adjustment liquid, and the lower the hydrogen ion concentration of the adjustment liquid (the higher the pH), the more easily the ozone gas dissolves in the adjustment liquid. tends to be difficult. Therefore, it is possible to keep the ozone concentration of the ozone water at an appropriate value by performing feedback control so as to adjust the hydrogen ion concentration of the adjustment liquid according to the ozone concentration acquired by the ozone concentration monitor.

Example 5. In the apparatus of Example 3 or Example 4, the path length of the liquid delivery line from the dissolving section to the ozone concentration monitor may be substantially equal to the path length of the liquid delivery line from the dissolving section to the at least one processing chamber. The ozone concentration of the ozonized water begins to attenuate immediately after the ozonized water is produced in the dissolving section. Therefore, by providing an ozone concentration monitor at a position equivalent to the path length of the liquid feed line from the dissolving part to at least one processing chamber, the ozone concentration of the ozonized water when supplied to at least one processing chamber can be monitored. Can be obtained indirectly. Therefore, it becomes possible to perform the cleaning process of the substrate with the ozone water with higher accuracy.

Example 6. In the apparatus of any one of Examples 1 to 5, the at least one processing chamber includes first and second processing chambers configured to clean the substrate with ozone water, and the liquid feed line is connected to the dissolving section to the first processing chamber and the second processing chamber. may be approximately equal to the path length from the unit to the second processing chamber. In this case, the attenuation amount of the ozone concentration until the ozone water reaches the first processing chamber from the dissolving section and the attenuation amount of the ozone concentration until the ozone water reaches the second processing chamber from the dissolving section are substantially equal. be equivalent. Therefore, a uniform cleaning result can be obtained regardless of whether the substrate is cleaned in the first or second processing chamber.

Example 7. In the apparatus of any of Examples 1-6, the conditioning liquid supply may be configured to mix water and an acidic solution to produce the conditioning liquid.

Example 8. In the apparatus of Example 7, the adjustment liquid supply may be configured to circulate the adjustment liquid. In this case, the water and the acid solution are sufficiently uniformly mixed during the circulation of the adjustment liquid. Therefore, it is possible to stably dissolve the ozone gas in the adjustment liquid in the dissolving section.

Example 9. The apparatus of any of Examples 1-8 may further comprise an alkaline solution supply configured to supply an alkaline solution to the liquid feed line. In this case, an alkaline solution that reduces the solubility of ozone gas in the adjustment liquid is mixed with the ozone water after the ozone water is produced. Therefore, it becomes possible to remove the deposits adhering to the substrate with the alkaline component while suppressing the decrease in the ozone concentration of the ozone water.

Example 10. The apparatus of any one of Examples 1-9 includes a temperature monitor configured to obtain the temperature of the conditioning liquid or ozone water and a hydrogen ion concentration monitor configured to obtain the hydrogen ion concentration of the conditioning liquid. an ozone concentration monitor configured to acquire the ozone concentration of the ozonated water; a temperature acquired by the temperature monitor is equal to or greater than a predetermined value; and a hydrogen ion concentration acquired by the hydrogen ion concentration is equal to or greater than a predetermined value; a control unit that controls the liquid sending unit to send the ozone water from the dissolving unit to at least one processing chamber when the ozone concentration acquired by the ozone concentration monitor is equal to or higher than a predetermined value. may be In this case, the ozone concentration of the ozone water supplied to at least one processing chamber is stably maintained at a predetermined value or higher. Therefore, it is possible to obtain a uniform cleaning result.

Example 11. The apparatus of any one of Examples 1 to 10 further includes a control unit, at least one processing chamber includes a plurality of processing chambers configured to clean the substrate with ozone water, and the liquid feed line comprises: The dissolving section branches toward each of the plurality of processing chambers, and the liquid feeding section is configured to feed the ozone water from the dissolving section to each of the plurality of processing chambers through the liquid feeding line. , the control unit controls the liquid sending unit so that, when the ozone water is being sent to one of the plurality of processing chambers, the ozone water is not sent to the remaining processing chambers of the plurality of processing chambers. You may perform the process to control. In this case, the cleaning process of the substrate with ozone water is not performed simultaneously in each chamber. Therefore, ozone water with a stable ozone concentration is supplied to each chamber. Therefore, a uniform cleaning result can be obtained regardless of which processing chamber the substrate is cleaned.

Example 12. The apparatus according to any one of Examples 1 to 11 is provided in the liquid feeding line, and has a drainage section configured to discharge the ozonized water to the outside of the system, and the ozonated water to be fed to at least one processing chamber. and a control unit that executes a process of controlling the drain unit so as to discharge the ozone water to the outside of the system when the ozone water is not discharged. In this case, it becomes difficult for the ozonized water to stay in the liquid feeding line, so that the ozone concentration of the ozonized water can be further stabilized.

Example 13. An example of a substrate processing method includes supplying ozone gas and an adjustment liquid having a predetermined hydrogen ion concentration to a dissolution unit, dissolving the ozone gas in the adjustment liquid to generate ozone water, and cleaning the substrate with the ozone water. feeding the ozonated water from the dissolving section through the liquid feeding line into at least one processing chamber configured to do so. In this case, the same effects as those of the device of Example 1 are obtained.

Example 14. The method of Example 13 may further include adjusting the hydrogen ion concentration of the adjustment liquid according to the ozone concentration of the ozone water flowing through the liquid feed line. In this case, the same effects as those of the device of Example 4 are obtained.

Example 15. In the method of Example 13 or Example 14, when the ozonized water is sent, the temperature of the adjustment liquid or the ozonized water is equal to or higher than a predetermined value, the hydrogen ion concentration of the adjustment liquid is equal to or higher than the predetermined value, and the ozonized water is The method may include sending ozonated water from the dissolving unit to the at least one processing chamber when the ozone concentration is equal to or greater than a predetermined value. In this case, the same effects as those of the device of Example 10 are obtained.

Example 16. The method of any one of Examples 13-15, wherein the at least one processing chamber includes a plurality of processing chambers configured to clean the substrate with ozonated water, and sending the ozonated water comprises a plurality of It may include not feeding the ozone water to the remaining processing chambers of the plurality of processing chambers when the ozone water is being fed to one of the processing chambers. In this case, the same effects as those of the device of Example 11 are obtained.

Example 17. The method of any one of Examples 13 to 16 may further include discharging the ozonated water out of the system when the ozonated water is not being sent to the at least one processing chamber. In this case, the same effect as the apparatus of Example 12 is obtained.

Example 18. An example of a computer-readable recording medium records a program for causing a substrate processing apparatus to execute any of the substrate processing methods of Examples 13-17. In this case, the same effects as those of any one of Examples 13 to 17 are obtained. In this specification, the computer-readable recording medium may be a non-transitory computer recording medium (for example, various main storage devices or auxiliary storage devices), or a propagated signal ( transitory computer recording medium) (eg, a data signal that can be provided over a network).

DESCRIPTION OF SYMBOLS 1... Substrate processing system 3... Processing station 4... Control apparatus 10... Substrate processing apparatus 16... Processing unit 18... Control part 100... Ozone water supply part 110... Ozone gas supply part 120... Adjustment liquid supply Part 126...Hydrogen ion concentration monitor 130...Dissolving part 140...Liquid sending part 142...Temperature monitor 143...Ozone concentration monitor 200...Alkaline solution supply part 300...Rinse solution supply part 400...Drainage part , 500... Exhaust part, D6 to D9... Piping (liquid feeding line), RM... Recording medium.

Claims (11)

an ozone gas supply unit configured to supply ozone gas;
an adjustment liquid supply unit configured to supply an adjustment liquid exhibiting a predetermined hydrogen ion concentration;
a dissolving unit configured to dissolve the ozone gas in the adjustment liquid to generate ozone water;
at least one processing chamber configured to clean a substrate with the ozonated water;
a liquid sending unit configured to send the ozone water from the dissolving unit to the at least one processing chamber through a liquid sending line;
an ozone concentration monitor provided in the liquid sending line and configured to acquire the ozone concentration of the ozone water downstream of the dissolving section;
a temperature monitor configured to acquire the temperature of the adjustment liquid or the ozone water;
a hydrogen ion concentration monitor configured to acquire the hydrogen ion concentration of the adjustment liquid;
and a control unit,
The control unit
Adjusting the hydrogen ion concentration of the adjustment liquid generated in the adjustment liquid supply unit according to the ozone concentration acquired by the ozone concentration monitor, and supplying the adjustment liquid so as to keep the ozone concentration at an appropriate value a process for controlling the unit;
When the temperature obtained by the temperature monitor is equal to or higher than a predetermined value, the hydrogen ion concentration obtained by the hydrogen ion concentration is equal to or higher than a predetermined value, and the ozone concentration obtained by the ozone concentration monitor is equal to or higher than a predetermined value. , a substrate processing apparatus configured to perform a process of controlling the liquid sending unit so as to send the ozone water from the dissolving unit to the at least one processing chamber. 2. The apparatus according to claim 1, further comprising a liquid drain section connected to said liquid feed line and configured to discharge said ozone water to the outside of the system. The control unit is configured to further execute a process of controlling the drain unit to discharge the ozonated water out of the system when the ozonated water is not sent to the at least one processing chamber. 3. The device of claim 2, wherein the device is 4. The method of claim 1, wherein the path length of the liquid feed line from the dissolving section to the ozone concentration monitor is substantially equal to the path length of the liquid feed line from the dissolving section to the at least one processing chamber. A device according to any one of the preceding clauses. the at least one processing chamber includes first and second processing chambers configured to clean the substrate with the ozone water;
the liquid sending line branches and extends from the dissolving section toward each of the first processing chamber and the second processing chamber;
3. A path length of said liquid feeding line from said dissolving section to said first processing chamber is substantially equal to a path length of said liquid feeding line from said dissolving section to said second processing chamber. 5. Apparatus according to any one of claims 1-4. The apparatus according to any one of claims 1 to 5, wherein the adjustment liquid supply unit is configured to mix water and an acid solution to produce the adjustment liquid. 7. The apparatus of claim 6, wherein the conditioning liquid supply is configured to circulate the conditioning liquid. The apparatus according to any one of claims 1 to 7, further comprising an alkaline solution supply configured to supply an alkaline solution to said liquid feed line. the at least one processing chamber includes a plurality of processing chambers configured to clean the substrate with the ozone water;
the liquid sending line branches and extends from the dissolving section toward each of the plurality of processing chambers,
The liquid sending unit is configured to send the ozone water from the dissolving unit to each of the plurality of processing chambers through the liquid sending line,
When the ozonized water is being sent to one of the plurality of processing chambers, the control unit prevents the ozonated water from being sent to the remaining processing chambers of the plurality of processing chambers. The device according to any one of claims 1 to 8, further configured to perform a process of controlling the liquid delivery section. supplying ozone gas and an adjustment liquid exhibiting a predetermined hydrogen ion concentration to a dissolving unit, and dissolving the ozone gas in the adjustment liquid to generate ozone water;
sending the ozone water from the dissolving unit through a liquid sending line to at least one processing chamber configured to clean a substrate with the ozone water;
adjusting the hydrogen ion concentration of the adjustment liquid according to the ozone concentration of the generated ozone water to keep the ozone concentration at an appropriate value;
The ozonated water is sent when the temperature of the adjustment liquid or the ozonized water is equal to or higher than a predetermined value, the hydrogen ion concentration of the adjustment liquid is equal to or higher than the predetermined value, and the ozone concentration of the ozonized water is equal to or higher than the predetermined value. A method of processing a substrate, sometimes comprising pumping ozonated water from a dissolution section to at least one processing chamber. A computer-readable recording medium recording a program for causing a substrate processing apparatus to execute the substrate processing method according to claim 10.

Images