JP7019430B2 - Substrate liquid processing equipment - Google Patents

Description

The present invention relates to a substrate liquid treatment apparatus that performs liquid treatment on a substrate such as a semiconductor wafer by immersing it in a treatment liquid stored in a treatment tank.

In the manufacture of semiconductor devices, in order to wet-etch a silicon nitride film formed on the surface of a substrate such as a semiconductor wafer, it is necessary to immerse a plurality of substrates in a heated phosphoric acid aqueous solution stored in a processing tank. It has been. In order to carry out this wet etching treatment efficiently and appropriately, it is necessary to maintain the phosphoric acid aqueous solution in an appropriate boiling state.

In Patent Document 1, the boiling state of the phosphoric acid aqueous solution is grasped based on the detected head pressure (back pressure) by using the configuration of the bubble type liquid level gauge, and the heater output or the heater output is based on the grasped boiling state. It is described that the injection amount of pure water is controlled. However, even with this control method, the boiling state cannot be controlled sufficiently stably.

Japanese Patent No. 3939630

An object of the present invention is to provide a substrate liquid treatment apparatus capable of more accurately controlling the boiling state of the treatment liquid in the treatment tank.

According to one embodiment of the present invention, the treatment tank in which the substrate is treated by storing the treatment liquid in a boiling state and immersing the substrate in the stored treatment liquid, and the treatment liquid are contained in the treatment liquid. Based on the concentration sensor that detects the concentration of the chemical solution component and the concentration detected by the concentration sensor, the chemical solution contained in the treatment solution is contained by adding the chemical solution component to the treatment solution or adding a diluting solution. A concentration adjusting unit that adjusts the concentration of the component to a set concentration, a water head pressure sensor that detects the water head pressure of the treatment liquid in the treatment tank, and the concentration adjusting unit based on the detection value of the water head pressure sensor. Provided is a substrate solution processing apparatus provided with a concentration set value correction calculation unit for correcting the set concentration given to the device.

According to the above embodiment, since the set concentration given to the concentration adjusting unit is corrected according to the grasped boiling level, the boiling state of the processing liquid in the processing tank can be controlled more accurately.

It is a schematic plan view which shows the whole structure of a substrate liquid processing system. It is a system diagram which shows the structure of the etching apparatus incorporated in the substrate liquid processing system. It is a graph which shows an example of the time-dependent change of the set value and the actual value of the boiling level, and the set value (corrected set value), and the actual value of a boiling level at the time of a test run of an etching apparatus. It is a schematic diagram which shows the modification embodiment which provided the temperature sensor at the outlet of the heater provided in the circulation line.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. First, the entire substrate liquid treatment system 1A in which the substrate liquid treatment apparatus (etching treatment apparatus) 1 according to the embodiment of the present invention is incorporated will be described.

As shown in FIG. 1, the substrate liquid processing system 1A includes a carrier loading / unloading unit 2, a lot forming unit 3, a lot loading unit 4, a lot transport unit 5, a lot processing unit 6, and a control unit 7. Has.

The carrier loading / unloading unit 2 carries in / out a carrier 9 in which a plurality of (for example, 25) substrates (silicon wafers) 8 are vertically arranged side by side in a horizontal posture.

The carrier loading / unloading section 2 includes a carrier stage 10 on which a plurality of carriers 9 are placed, a carrier transport mechanism 11 for transporting the carriers 9, carrier stocks 12 and 13 for temporarily storing the carriers 9, and carriers. A carrier mounting table 14 on which the 9 is mounted is provided. The carrier stock 12 temporarily stores the substrate 8 as a product before being processed by the lot processing unit 6. The carrier stock 13 is temporarily stored after the substrate 8 to be a product is processed by the lot processing unit 6.

The carrier loading / unloading section 2 transports the carrier 9 carried into the carrier stage 10 from the outside to the carrier stock 12 and the carrier mounting table 14 using the carrier transport mechanism 11. Further, the carrier loading / unloading section 2 transports the carrier 9 mounted on the carrier mounting table 14 to the carrier stock 13 and the carrier stage 10 by using the carrier transport mechanism 11. The carrier 9 conveyed to the carrier stage 10 is carried out.

The lot forming unit 3 forms a lot consisting of a plurality of (for example, 50) substrates 8 to be processed simultaneously by combining the substrates 8 housed in one or a plurality of carriers 9. When forming a lot, the lot may be formed so that the surfaces on which the pattern is formed on the surface of the substrate 8 face each other, and the surface on which the pattern is formed on the surface of the substrate 8 may be formed. Lots may be formed so that they all face one side.

The lot forming portion 3 is provided with a substrate transfer mechanism 15 for transporting a plurality of substrates 8. The substrate transfer mechanism 15 can change the posture of the substrate 8 from the horizontal posture to the vertical posture and from the vertical posture to the horizontal posture during the transfer of the substrate 8.

The lot forming unit 3 transfers the substrate 8 from the carrier 9 mounted on the carrier mounting table 14 to the lot mounting unit 4 by using the substrate transfer mechanism 15, and transfers the substrate 8 forming the lot to the lot mounting unit 4. Place it. Further, the lot forming unit 3 transfers the lot placed on the lot mounting unit 4 to the carrier 9 mounted on the carrier mounting table 14 by the substrate transfer mechanism 15. The substrate transfer mechanism 15 has, as a substrate support portion for supporting a plurality of substrates 8, a pre-processing substrate support portion that supports the substrate 8 before processing (before being transported by the lot transport unit 5) and a processing. It has two types of post-processed substrate support portions that support the post-processed substrate 8 (after being transported by the lot transport unit 5). This prevents particles and the like adhering to the substrate 8 and the like before the treatment from being transferred to the substrate 8 and the like after the treatment.

The lot loading unit 4 temporarily places (stands by) the lot transferred between the lot forming unit 3 and the lot processing unit 6 by the lot transport unit 5 on the lot loading table 16.

The lot loading unit 4 has a lot loading table 17 on the carry-in side on which the lot before processing (before being transported by the lot transport unit 5) is placed, and after processing (after being transported by the lot transfer unit 5). A carry-out side lot loading table 18 for loading lots is provided. A plurality of substrates 8 for one lot are placed side by side in a vertical position on the carry-in side lot mounting table 17 and the carry-out side lot mounting table 18.

In the lot loading unit 4, the lot formed by the lot forming unit 3 is placed on the loading side lot loading table 17, and the lot is carried into the lot processing unit 6 via the lot transport unit 5. Further, in the lot loading section 4, the lot carried out from the lot processing section 6 via the lot transport section 5 is placed on the carry-out side lot loading table 18, and the lot is conveyed to the lot forming section 3.

The lot transfer unit 5 transfers lots between the lot loading unit 4 and the lot processing unit 6 and between the inside of the lot processing unit 6.

The lot transport unit 5 is provided with a lot transport mechanism 19 for transporting lots. The lot transfer mechanism 19 is composed of a rail 20 arranged along the lot loading unit 4 and the lot processing unit 6, and a moving body 21 that moves along the rail 20 while holding a plurality of substrates 8. The moving body 21 is provided with a board holding body 22 that holds a plurality of boards 8 arranged in a vertical posture in a vertical position so as to be able to move forward and backward.

The lot transfer unit 5 receives the lot placed on the carry-in side lot loading table 17 by the substrate holder 22 of the lot transfer mechanism 19, and delivers the lot to the lot processing unit 6. Further, the lot transfer unit 5 receives the lot processed by the lot processing unit 6 by the substrate holder 22 of the lot transfer mechanism 19, and delivers the lot to the unloading side lot mounting table 18. Further, the lot transfer unit 5 transfers the lot inside the lot processing unit 6 by using the lot transfer mechanism 19.

The lot processing unit 6 performs processing such as etching, cleaning, and drying with a plurality of substrates 8 arranged in a vertical position in a vertical position as one lot.

The lot processing unit 6 includes a drying processing device 23 that performs drying processing of the substrate 8, a substrate holding body cleaning processing device 24 that performs cleaning processing of the substrate holding body 22, and a cleaning processing device 25 that performs cleaning processing of the substrate 8. And two etching processing devices (board liquid processing device) 1 according to the present invention that perform etching processing on the substrate 8 are provided side by side.

The drying processing device 23 has a processing tank 27 and a substrate elevating mechanism 28 provided in the processing tank 27 so as to be able to move up and down. A processing gas for drying (IPA (isopropyl alcohol) or the like) is supplied to the processing tank 27. A plurality of substrates 8 for one lot are held side by side in a vertical posture in the substrate elevating mechanism 28. The drying processing device 23 receives a lot from the substrate holding body 22 of the lot transfer mechanism 19 by the substrate elevating mechanism 28, and raises and lowers the lot by the substrate elevating mechanism 28, thereby using the processing gas for drying supplied to the processing tank 27. The substrate 8 is dried. Further, the drying processing device 23 transfers the lot from the substrate elevating mechanism 28 to the substrate holder 22 of the lot transfer mechanism 19.

The substrate holder cleaning treatment apparatus 24 has a treatment tank 29, and can supply a treatment liquid for cleaning and a drying gas to the treatment tank 29, and the substrate holder 22 of the lot transfer mechanism 19 is used for cleaning. After the treatment liquid of No. 1 is supplied, the substrate holder 22 is cleaned by supplying a dry gas.

The cleaning processing apparatus 25 has a processing tank 30 for cleaning and a processing tank 31 for rinsing, and the substrate elevating mechanisms 32 and 33 are provided in the processing tanks 30 and 31 so as to be able to move up and down. A cleaning treatment liquid (SC-1 or the like) is stored in the cleaning treatment tank 30. A rinsing treatment liquid (pure water or the like) is stored in the rinsing treatment tank 31.

The etching processing apparatus 1 has a processing tank 34 for etching and a processing tank 35 for rinsing, and the substrate elevating mechanisms 36 and 37 are provided in the processing tanks 34 and 35 so as to be able to move up and down. An etching treatment liquid (phosphoric acid aqueous solution) is stored in the etching treatment tank 34. A rinsing treatment liquid (pure water or the like) is stored in the rinsing treatment tank 35.

The cleaning processing device 25 and the etching processing device 1 have the same configuration. Explaining the etching processing apparatus (substrate liquid processing apparatus) 1, the substrate elevating mechanism 36 holds a plurality of substrates 8 for one lot side by side in a vertical posture. In the etching processing apparatus 1, the lot is received from the substrate holder 22 of the lot transfer mechanism 19 by the substrate elevating mechanism 36, and the lot is elevated and lowered by the substrate elevating mechanism 36 to immerse the lot in the etching processing liquid of the processing tank 34. Then, the substrate 8 is etched. After that, the etching processing device 1 transfers the lot from the substrate elevating mechanism 36 to the substrate holder 22 of the lot transfer mechanism 19. Further, the lot is received from the substrate holder 22 of the lot transfer mechanism 19 by the substrate elevating mechanism 37, and the lot is elevated and lowered by the substrate elevating mechanism 37 so that the lot is immersed in the rinsing treatment liquid of the processing tank 35 and the substrate 8 is used. Rinse. After that, the lot is delivered from the substrate elevating mechanism 37 to the substrate holder 22 of the lot transfer mechanism 19.

The control unit 7 controls the operation of each unit of the substrate liquid processing system 1A (carrier loading / unloading unit 2, lot forming unit 3, lot loading unit 4, lot transport unit 5, lot processing unit 6, etching processing device 1). ..

The control unit 7 is composed of, for example, a computer, and includes a storage medium 38 that can be read by the computer. The storage medium 38 stores programs that control various processes executed in the substrate liquid processing device 1. The control unit 7 controls the operation of the substrate liquid processing device 1 by reading and executing the program stored in the storage medium 38. The program may be stored in a storage medium 38 readable by a computer, and may be installed in the storage medium 38 of the control unit 7 from another storage medium. Examples of the storage medium 38 readable by a computer include a hard disk (HD), a flexible disk (FD), a compact disk (CD), a magnet optical disk (MO), and a memory card.

As described above, in the treatment tank 34 of the etching treatment apparatus 1, the substrate 8 is liquid-treated (etched) using an aqueous solution (phosphoric acid aqueous solution) of a chemical (phosphoric acid) having a predetermined concentration as a treatment liquid (etching liquid).

Next, a configuration related to the etching processing apparatus (substrate liquid processing apparatus) 1, particularly the processing tank 34 for etching thereof, will be described with reference to FIG.

The etching treatment apparatus 1 has the above-mentioned treatment tank 34 for storing a phosphoric acid aqueous solution having a predetermined concentration as a treatment liquid. The treatment tank 34 has an inner tank 34A having an open upper portion and an outer tank 34B provided around the inner tank 34A and having an open upper portion. The phosphoric acid aqueous solution overflowing from the inner tank 34A flows into the outer tank 34B. The outer tank 34B surrounds the upper part of the inner tank 34A as shown in FIG. The outer tank 34B may be configured to accommodate the inner tank 34A inside. The treatment tank 34 is provided with an openable / closable lid 70 that covers at least the upper opening of the inner tank 34A in order to keep the phosphoric acid aqueous solution warm and prevent the phosphoric acid aqueous solution from scattering.

One end of the circulation line 50 is connected to the bottom of the outer tank 34B. The other end of the circulation line 50 is connected to the processing liquid supply nozzle 49 installed in the inner tank 34A. A pump 51, a heater 52, and a filter 53 are interposed in the circulation line 50 in order from the upstream side. By driving the pump 51, a circulating flow of the phosphoric acid aqueous solution is formed, which is sent from the outer tank 34B through the circulation line 50 and the treatment liquid supply nozzle 49 into the inner tank 34A and flows out to the outer tank 34B again. .. A gas nozzle (not shown) may be provided below the treatment liquid supply nozzle 49 in the inner tank 34A, and an inert gas such as nitrogen gas may be bubbling in order to stabilize the boiling state of the phosphoric acid aqueous solution.

The liquid treatment section 39 is formed by the treatment tank 34, the circulation line 50, and the equipment (51, 52, 53, etc.) in the circulation line 50. Further, a circulation system is configured by the treatment tank 34 and the circulation line 50.

The etching treatment device 1 supplies a phosphoric acid aqueous solution supply unit 40 that supplies a phosphoric acid aqueous solution to the liquid treatment unit 39, a pure water supply unit 41 that supplies pure water to the liquid treatment unit 39, and a silicon solution to the liquid treatment unit 39. It has a silicon supply unit 42 to supply and a phosphoric acid aqueous solution discharge unit 43 to discharge the phosphoric acid aqueous solution from the liquid treatment unit 39.

The phosphoric acid aqueous solution supply unit 40 applies a phosphoric acid aqueous solution having a predetermined concentration to any part of the circulation system including the treatment tank 34 and the circulation line 50, that is, the liquid treatment unit 39, preferably the outer tank 34B as shown in the figure. Supply. The phosphoric acid aqueous solution supply unit 40 includes a phosphoric acid aqueous solution supply source 40A including a tank for storing the phosphoric acid aqueous solution, a phosphoric acid aqueous solution supply line 40B connecting the phosphoric acid aqueous solution supply source 40A and the outer tank 34B, and a phosphoric acid aqueous solution. It has a flow meter 40C, a flow control valve 40D, and an on-off valve 40E, which are interposed in the supply line 40B in order from the upstream side. The phosphoric acid aqueous solution supply unit 40 can supply the phosphoric acid aqueous solution to the outer tank 34B at a controlled flow rate via the flow meter 40C and the flow control valve 40D.

The pure water supply unit 41 supplies pure water to replenish the water evaporated by heating the phosphoric acid aqueous solution. The pure water supply unit 41 includes a pure water supply source 41A that supplies pure water at a predetermined temperature, and the pure water supply source 41A is connected to the outer tank 34B via a flow rate controller 41B. The flow rate controller 41B can be composed of an on-off valve, a flow rate control valve, a flow meter, and the like.

The silicon supply unit 42 has a silicon supply source 42A including a tank for storing a silicon solution, for example, a liquid in which colloidal silicon is dispersed, and a flow rate controller 42B. The flow rate controller 42B can be composed of an on-off valve, a flow rate control valve, a flow meter, and the like.

The phosphoric acid aqueous solution discharge unit 43 is provided to discharge the phosphoric acid aqueous solution in the circulation system including the liquid treatment unit 39 and the circulation line 50, that is, in the liquid treatment unit 39. The phosphoric acid aqueous solution discharge unit 43 includes a discharge line 43A branching from the circulation line 50, a flow meter 43B sequentially provided in the discharge line 43A from the upstream side, a flow control valve 43C, an on-off valve 43D, and a cooling tank 43E. The phosphoric acid aqueous solution discharge unit 43 can discharge the phosphoric acid aqueous solution at a controlled flow rate via the flow meter 43B and the flow control valve 43C.

The cooling tank 43E temporarily stores and cools the phosphoric acid aqueous solution flowing through the discharge line 43A. The phosphoric acid aqueous solution (see reference numeral 43F) flowing out of the cooling tank 43E may be discarded in a factory waste liquid system (not shown), or silicon contained in the phosphoric acid aqueous solution may be recycled (not shown). After being removed by the above method, it may be sent to the phosphoric acid aqueous solution supply source 40A for reuse.

In the illustrated example, the discharge line 43A is connected to the circulation line 50 (the position of the filter drain in the figure), but is not limited to this, and is connected to another part in the circulation system, for example, the bottom of the inner tank 34A. It may have been done.

The discharge line 43A is provided with a silicon densitometer 43G for measuring the silicon concentration in the aqueous phosphoric acid solution. Further, phosphorus for measuring the phosphoric acid concentration in the phosphoric acid aqueous solution at the branch line 55A (this branch line 55A can also be regarded as a part of the circulation system) branched from the circulation line 50 and connected to the outer tank 34B. An acid concentration meter 55B is provided. The outer tank 34B is provided with a liquid level gauge 44 for detecting the liquid level in the outer tank 34B.

In the inner tank 34A, a temperature sensor 60 for detecting the temperature of the phosphoric acid aqueous solution in the inner tank 34A is provided. The temperature sensor 60 may be provided in a place other than the inner tank 34A in the circulation system, for example, in the vicinity of the outlet of the heater 52 of the circulation line 50.

A bubble type liquid level gauge 80 is attached to the inner tank 34A. The bubble type liquid level gauge 80 has a bubble tube 81 inserted into the phosphoric acid aqueous solution in the inner tank 34A, and a purge set 82 for supplying a purge gas (here, nitrogen gas) to the bubble tube 81. The bubble tube 81 is made of a material having resistance to an aqueous solution of phosphoric acid, for example, quartz.

The purge set 82 includes a pressure reducing valve, a throttle, a rotor meter (none of which is shown), and the like. The purge set 82 controls so that the purge gas supplied from the pressurized gas supply source 83 (for example, the power system of the factory) is discharged from the tip of the bubble tube 81 inserted in the phosphoric acid aqueous solution at a constant flow rate. ..

A detection line 85 is connected to the gas line 84 connecting the bubble tube 81 and the purge set 82, and the detection line 85 further branches into two branch detection lines, that is, a first branch detection line 85A and a second branch detection line 85B. ing. The first detector 86A and the second detector 86B are connected to the first and second branch detection lines 85A and 85B, respectively. The first and second detectors 86A and 86B measure the back pressure of the purge gas corresponding to the head pressure applied to the tip of the bubble tube 81 (the head pressure of the phosphoric acid aqueous solution in the inner tank 34A).

Since the purge gas is constantly flowed through the gas line 84, it is not necessary to manufacture the gas line 84, the detection line 85, the first branch detection line 85A and the second branch detection line 85B from quartz, and suitable corrosion resistant resins such as PTFE and PFA. It can be manufactured by such as.

The same pressure is applied to the first detector 86A and the second detector 86B. However, the detection ranges of the first detector 86A and the second detector 86B are different from each other.

The first detector 86A has the highest level (inside) from the water head pressure applied to the tip of the bubble tube 81 when the liquid level of the phosphoric acid aqueous solution in the inner tank 34A is the lowest level (the inner tank 34A is empty). It is set so that the pressure in the range up to the water head pressure applied to the tip of the bubble tube 81 can be detected when the phosphoric acid aqueous solution overflows from the tank 34A to the outer tank 34B). That is, the first detector 86A is provided to measure the liquid level of the phosphoric acid aqueous solution in the inner tank 34A.

The second detector 86B determines the boiling level of the phosphoric acid aqueous solution when the liquid level of the phosphoric acid aqueous solution in the inner tank 34A is at the highest level (that is, when an overflow occurs from the inner tank 34A to the outer tank 34B). The range from the head pressure applied to the tip of the bubble tube 81 when is maximum to the head pressure applied to the tip of the bubble tube 81 when the phosphoric acid aqueous solution is not boiling at all (detection target range). It is set so that pressure can be detected.

When the boiling level (boiling state) changes, the amount of bubbles in the aqueous phosphoric acid solution changes, so that the head pressure applied to the tip of the bubble tube 81 also changes. That is, the head pressure decreases as the boiling level increases, and the head pressure increases as the boiling level decreases. The boiling level is quantified by visually or image analysis of the size and number of bubbles in the phosphoric acid aqueous solution and the liquid level state of the phosphoric acid aqueous solution (“flat”, “largely wavy”, etc.). (For example, in 5 steps of boiling levels 1-5). Through experiments, the relationship between the head pressure (HP) and the boiling level (BL) can be grasped, and this relationship can be expressed in the form of the function BL = f (HP). Although there is some variation, the head pressure (HP) decreases monotonically as the boiling level (BL) increases.

The above function is stored in, for example, the storage medium 38 of the control unit 7. This makes it possible to grasp the boiling level (boiling state) of the phosphoric acid aqueous solution in the inner tank 34A based on the head pressure detected by the second detector 86B. That is, the bubble type liquid level gauge 80 acts as a boiling level sensor.

Preferably, the second detector 86B is out of the detection target range described above by an electric circuit (for example, having a high-pass filter function and an amplification function) for processing the sensor output of the second detector 86B, or by arithmetic processing by software. On the other hand, it improves the pressure detection resolution within the detection target range. As a result, the second detector 86B substantially loses the ability to detect the liquid level of the phosphoric acid aqueous solution in the inner tank 34A, but instead, it becomes possible to detect the boiling state with higher accuracy.

Specifically, for example, the output voltage (changes in response to changes in the head pressure) of the pressure sensor (not shown) in the second detector 86B when the phosphoric acid aqueous solution is not boiling at all is 5 V. It is assumed that the output voltage of the second detector 86B when the boiling level of the phosphoric acid aqueous solution is the highest level is 4V. In this case, the detection circuit provided in the second detector 86B is a value obtained by subtracting 4 V from the output voltage of the pressure sensor (actually, an appropriate margin is set) and multiplying it by a predetermined gain (constant value). Is configured to be output.

In the substrate liquid processing apparatus 1, each unit (carrier loading / unloading unit 2, lot forming unit 3, lot loading unit 4, lot transport unit 5, lot processing unit 6) is controlled by the control unit 7 according to the process recipe stored in the storage medium 38. The substrate 8 is processed by controlling the operation of the etching processing apparatus 1). The operating parts (off-off valve, flow rate control valve, pump, heater, etc.) of the etching processing apparatus 1 operate based on the operation command signal transmitted from the control unit 7. Further, a signal indicating the detection result is sent from the sensors (43G, 55B, 86A, 86B, etc.) to the control unit 7, and the control unit 7 uses the detection result to control the operating component.

Next, the operation of the etching processing apparatus 1 will be described. First, the phosphoric acid aqueous solution supply unit 40 supplies the phosphoric acid aqueous solution to the outer tank 34B of the liquid treatment unit 39. When a predetermined time elapses after the start of supply of the phosphoric acid aqueous solution, the pump 51 of the circulation line 50 operates to form a circulating flow circulating in the above-mentioned circulation system.

Further, the heater 52 of the circulation line 50 is activated to heat the phosphoric acid aqueous solution so that the phosphoric acid aqueous solution in the inner tank 34A reaches a predetermined temperature (for example, 160 ° C.). The lid 70 is closed by the start of heating by the heater 52 at the latest, and at least the upper opening of the inner tank 34A is covered with the lid 70. The phosphoric acid aqueous solution at 160 ° C. is in a boiling state.

Silicon concentration in the phosphoric acid aqueous solution present in the circulation system (including the inner tank 34A, the outer tank 34B and the circulation line 50) before charging the substrate 8 of one lot into the phosphoric acid aqueous solution in the inner tank 34A. (This affects the etching selectivity of the silicon nitride film to the silicon oxide film) is adjusted. The silicon concentration can be adjusted by immersing the dummy substrate in the phosphoric acid aqueous solution in the inner tank 34A or by supplying the silicon solution from the silicon supply unit 42 to the outer tank 34B. In order to confirm that the concentration of silicon in the aqueous solution of phosphoric acid existing in the circulation system is within a predetermined range, the aqueous solution of phosphoric acid is flowed through the discharge line 43A, and the concentration of silicon is measured by a silicon densitometer 43G. May be good.

After the silicon concentration adjustment is completed, the lid 70 is opened to form a plurality of sheets, that is, one lot (also referred to as a processing lot or a batch) held by the substrate elevating mechanism 36 in the phosphoric acid aqueous solution in the inner tank 34A. A plurality of, for example, 50 substrates 8 are immersed. Immediately thereafter, the lid 70 is closed. By immersing the substrate 8 in a phosphoric acid aqueous solution for a predetermined time, the substrate 8 is subjected to a wet etching treatment (liquid treatment).

While the substrate 8 is subjected to the wet etching process, the control unit 7 performs the following control.

[Temperature control]
The control unit 7 feedback-controls the output of the heater 52 so that the temperature of the phosphoric acid aqueous solution in the inner tank 34A detected by the temperature sensor 60 becomes the set temperature. In this feedback control, the set temperature is the set value SV, the detection temperature of the temperature sensor 60 is the measured value (PV), and the output of the heater 52 is the operation amount MV. The temperature control unit is configured by the control unit 7 and the heater 52.

In addition, in this embodiment, the set temperature of the phosphoric acid aqueous solution is not changed according to the change of the phosphoric acid concentration or the change of the set concentration of the phosphoric acid concentration, and is maintained at the value predetermined in the process recipe. Will be done.

[Concentration control]
The control unit 7 is required to set the concentration of phosphoric acid (chemical solution component) in the phosphoric acid aqueous solution (treatment solution) in the circulation system detected by the phosphoric acid concentration meter 55B (concentration sensor). The amount of pure water (diluted solution) supplied from the pure water supply unit 41 to the circulation system (outer tank 34B in the illustrated example), or from the phosphoric acid aqueous solution supply unit 40 to the circulation system (outer tank 34B in the illustrated example). The amount of phosphoric acid supplied is controlled by feedback. In this feedback control, the set concentration is the set value SV, the detection concentration of the phosphoric acid concentration meter 55B is the measured value (PV), and the pure water (diluted solution) from the pure water supply unit 41 to the circulation system (outer tank 34B in the illustrated example). ), Or the amount of phosphoric acid supplied from the phosphoric acid aqueous solution supply unit 40 to the circulation system (outer tank 34B in the illustrated example) is the operation amount MV. The concentration adjusting unit is composed of the control unit 7, the pure water supply unit 41, and the phosphoric acid aqueous solution supply unit 40. As the set concentration, a predetermined value is used as an initial value in the process recipe, but it is corrected by the boiling level control described later.

In the present embodiment, the phosphoric acid aqueous solution is used as the treatment liquid, and the phosphoric acid aqueous solution is constantly boiling during the treatment of the substrate 8, so that the pure water content in the phosphoric acid aqueous solution always tends to decrease. Yes, the phosphoric acid concentration is constantly increasing. Therefore, what is supplied into the circulatory system for concentration control is exclusively pure water.

[Boiling level control]
Initial values are set in the process recipe for the set concentration of phosphoric acid (chemical solution component) in the phosphoric acid aqueous solution (treatment solution). At the beginning of control, the above-mentioned concentration control is performed based on the initial value of the set concentration.

The control unit 7 determines when the boiling level of the phosphoric acid aqueous solution in the inner tank 34A, which is grasped based on the head pressure detected by the second detector 86B, deviates from or deviates from the optimum level (for example, boiling level 4). When that happens, correct the set density. For example, when the boiling level is lower than the optimum level (for example, there are few and / or small bubbles in the aqueous phosphoric acid solution) or when it is about to be low, the set concentration is lowered. On the other hand, when the boiling level becomes higher than the optimum level (for example, the surface in the phosphoric acid aqueous solution is violently wavy) or when it is about to become high, the set concentration is increased.

Since it is not desirable for the boiling level to deviate from the optimum level, the set concentration is corrected so as to cancel the change in head pressure when a change in head pressure that can predict that the boiling level is likely to deviate from the optimum level is confirmed. It is preferable to perform such control.

For example, the median output voltage of the sensor of the second detector 86B at the optimum boiling level (for example, boiling level 4) is 4V, and the output voltage of the sensor of the second detector 86B having the optimum boiling level is 4V ± 0. It is assumed that the optimum boiling level can be achieved at 2V. At this time, for example, when the output voltage of the sensor of the second detector 86B increases from 4V to 4.1V, even if the optimum boiling level is maintained regardless of this change, the set concentration is changed by a small amount. It is preferable to perform control to correct the set concentration so as to prevent the output voltage from approaching 4.2 V any more. As an example, the initial value of the concentration set value is about 88%, and the concentration set value can be corrected in 0.02 wt% increments.

In addition, in order to prevent hunting at the boiling level, it is preferable that the control unit 7 controls with a hysteresis (control dead zone). Further, since the degree of influence of the concentration change range on the boiling level differs depending on whether the boiling level is higher or lower than the optimum level, it is preferable to correct the change range with the respective optimum values. The optimum value of the change range is determined by the chemical temperature, concentration, and boiling state used for the process recipe, and is a unique value set for each process recipe.

In the present embodiment, only the set concentration is corrected according to the detected boiling level, and the set temperature is not corrected. The actual temperature of the phosphoric acid aqueous solution can be controlled with high accuracy by the above temperature control, for example, within the range of about ± 0.1 to 0.2 ° C. of the set temperature.

FIG. 3 shows a set value (line A) and an actual value (line B) of the boiling level, and a set value (corrected set value) (corrected setting value) of the boiling level when the etching apparatus is test-operated based on the above control method. An example of the change over time between C) and the actual value (line D) is shown. The vertical axis on the left side is the output voltage of the sensor of the second detector 86B, and the median value (this is the target value) of the output voltage when the optimum boiling state is realized is 4V. The vertical axis on the left is the concentration of phosphoric acid in the aqueous solution of phosphoric acid. The horizontal axis is the elapsed time (seconds). The target value (set concentration) of the phosphoric acid concentration is corrected in 0.02 wt% increments. As shown in FIG. 3, it can be seen that a stable boiling state was obtained for 500 seconds to 5500 seconds. Although not shown in FIG. 3, the temperature of the aqueous phosphoric acid solution was maintained within the range of about 160 ° C. ± 0.1 to 0.2 ° C. for 500 seconds to 5500 seconds.

In addition to the above three feedback controls, the silicon concentration in the phosphoric acid aqueous solution may be controlled while the substrate 8 is subjected to the wet etching treatment. Since silicon is eluted from the substrate 8 during the processing of the substrate 8 in one lot, the concentration of silicon in the aqueous phosphoric acid solution existing in the circulation system increases. In order to maintain or intentionally change the concentration of silicon in the phosphoric acid aqueous solution existing in the circulating system during the processing of the substrate 8 of one lot, the phosphoric acid aqueous solution discharging unit 43 puts the silicon solution into the circulating system. The phosphoric acid aqueous solution (new solution) can be supplied by the phosphoric acid aqueous solution supply unit 40 while discharging a certain phosphoric acid aqueous solution. The silicon solution may be supplied from the silicon supply unit 42. However, since it is difficult to feedback-control the silicon concentration in real time, it is desirable to control the silicon concentration by discharging and supplying the liquid at a timing predetermined by the process recipe.

When the processing of the substrate 8 of one lot is completed as described above, the lid 70 is opened and the substrate 8 is carried out from the inner tank 34A. The carried-out substrate 8 is carried into the adjacent processing tank 35, where the rinsing process is performed.

After that, the lid 70 is closed, the temperature, the phosphoric acid concentration, and the silicon concentration of the phosphoric acid aqueous solution in the circulation system are adjusted, and then the substrate 8 of another lot is processed in the same manner as described above.

In the above embodiment, the control unit 7 is responsible for the control functions of the concentration adjustment unit, the temperature adjustment unit, and the concentration set value correction calculation unit, but is not limited to this, and the concentration adjustment unit, the temperature adjustment unit, and the temperature adjustment unit are not limited to this. At least one control function of the density setting value correction calculation unit may be realized by another computer.

According to the above embodiment, the boiling state (boiling level) of the phosphoric acid aqueous solution in the inner tank 34A is grasped based on the detection value of the second detector 86B which is a water head pressure sensor, and this boiling state is maintained at the target state. Since the set concentration is corrected so as to be performed and the feedback control of the concentration is performed based on the corrected set concentration, it becomes easy to maintain the boiling level of the phosphoric acid aqueous solution in the inner tank 34A in the optimum state. In addition, by controlling the boiling level by concentration correction, it is possible to simultaneously control the concentration that affects the process performance.

Next, a method for evaluating the soundness of the boiling level sensor (bubble level gauge 80) will be described.

The temperature of the aqueous phosphoric acid solution, the concentration of the aqueous phosphoric acid solution and the boiling level of the aqueous phosphoric acid solution have a close correlation. Therefore, if the detected value of a temperature sensor (for example, temperature sensor 60) that detects the temperature of the aqueous phosphate solution is not stable at the set temperature (specifically, the temperature within the allowable range based on the set temperature), boiling occurs. There may be something wrong with the level sensor.

Further, if the detected concentration of the phosphoric acid densitometer 55B is not stable at the set concentration (specifically, the concentration within the permissible range based on the set concentration), there is a possibility that the boiling level sensor has an abnormality.

Furthermore, if the amount of pure water supplied by the pure water supply unit 41 is excessive or too small, there is a possibility that the boiling level sensor has an abnormality. That is, if the treatment conditions, specifically the temperature and boiling level of the aqueous phosphate solution in the circulation system, are properly controlled, the amount of water lost due to evaporation by boiling per unit time is generally constant. Therefore, the amount of pure water per unit time replenished to the circulation system from the pure water supply unit 41 should be within a predetermined range (note that pure water is continuously circulated from the pure water supply unit 41. The system may be replenished, or the circulation system may be replenished intermittently.) Therefore, when the amount of pure water supplied from the pure water supply unit 41 per unit time deviates from the above-mentioned predetermined range. , There may be something wrong with the boiling level sensor.

The control unit 7 is found to have an abnormality in the detection value of the temperature sensor described above, an abnormality in the detection value of the phosphoric acid concentration meter 55B, or an abnormality in the amount of pure water supplied by the pure water supply unit 41, or an abnormality is found. If it continues for more than a predetermined time, the operator of the substrate processing device is alerted that an abnormality may have occurred in the boiling level sensor (bubble level gauge 80), and the operator is informed. Prompt inspection of boiling level sensor. Further, the control unit 7 may warn the operator that there is a suspicion that a processing defect has occurred in the substrate 8 of the lot processed at that time.

As shown in FIG. 4, a temperature sensor 60A may be provided at the outlet of the heater 52, and the output of the heater 52 (power supplied to the heater 52) may be controlled based on the detection value of the temperature sensor 60A. In this case, if the detection value of the temperature sensor 60A is not stable at the set temperature (specifically, the temperature within the allowable range based on the set temperature), it is determined that there is a possibility that the boiling level sensor has an abnormality. You may.

The soundness of the boiling level sensor (bubble level gauge 80) is evaluated when the heater temperature is relatively stable, specifically, for example, when the substrate 8 is not processed in the processing tank 34. It is preferable to do so.

In the above embodiment, the treatment liquid is an aqueous phosphoric acid solution, but the treatment liquid is not limited to this. The treatment liquid may be any as long as the concentration changes due to boiling and the treatment state of the substrate changes depending on the boiling state. Further, the substrate is not limited to the semiconductor wafer, and may be another type of substrate such as a glass substrate or a ceramic substrate.

7 Concentration setting value correction calculation unit 7, 52 Temperature adjustment unit 7, 40, 41 Concentration adjustment unit 34 Processing tank 34A Inner tank 34B Outer tank 50 Circulation line 51 Pump 52 Heater 55B Concentration sensor (phosphoric acid densitometer)
60,60A Temperature sensor 86B Head pressure sensor (second detector)

Claims (12)

A treatment tank in which the substrate is treated by storing the treatment liquid in a boiling state and immersing the substrate in the stored treatment liquid.
A concentration sensor that detects the concentration of the drug solution component contained in the treatment solution, and
Based on the concentration detected by the concentration sensor, the chemical solution component is added to the treatment solution or a diluted solution is added to adjust the concentration of the chemical solution component contained in the treatment solution to the set concentration. Concentration adjustment unit and
A head pressure sensor that detects the head pressure of the treatment liquid in the treatment tank, and
A concentration setting value correction calculation unit that corrects the set concentration given to the concentration adjustment unit based on the detection value of the head pressure sensor, and a concentration setting value correction calculation unit.
Equipped with
The head pressure sensor is a substrate liquid treatment apparatus set so as to be able to detect a pressure in a range narrower than a detection range for measuring the liquid level of the treatment liquid in the treatment tank . A treatment tank in which the substrate is treated by storing the treatment liquid in a boiling state and immersing the substrate in the stored treatment liquid.
A concentration sensor that detects the concentration of the drug solution component contained in the treatment solution, and
Based on the concentration detected by the concentration sensor, the chemical solution component is added to the treatment solution or a diluted solution is added to adjust the concentration of the chemical solution component contained in the treatment solution to the set concentration. Concentration adjustment unit and
A head pressure sensor that detects the head pressure of the treatment liquid in the treatment tank, and
A concentration setting value correction calculation unit that corrects the set concentration given to the concentration adjustment unit based on the detection value of the head pressure sensor, and a concentration setting value correction calculation unit.
A control unit that generates an alarm warning that an abnormality may have occurred in the head pressure sensor when the concentration of the chemical solution component detected by the concentration sensor is not stable at the set concentration.
A substrate liquid processing device equipped with . A treatment tank in which the substrate is treated by storing the treatment liquid in a boiling state and immersing the substrate in the stored treatment liquid.
A concentration sensor that detects the concentration of the drug solution component contained in the treatment solution, and
Based on the concentration detected by the concentration sensor, the chemical solution component is added to the treatment solution or a diluted solution is added to adjust the concentration of the chemical solution component contained in the treatment solution to the set concentration. Concentration adjustment unit and
A head pressure sensor that detects the head pressure of the treatment liquid in the treatment tank, and
A concentration setting value correction calculation unit that corrects the set concentration given to the concentration adjustment unit based on the detection value of the head pressure sensor, and a concentration setting value correction calculation unit.
If the amount of the diluted solution added to the treated liquid from the concentration adjusting unit per unit time is not the amount corresponding to the treatment conditions, an alarm warning that the head pressure sensor may be abnormal is issued. The control unit to generate and
A substrate liquid processing device equipped with . A temperature sensor that detects the temperature of the treatment liquid and
A temperature adjusting unit that adjusts the temperature of the processing liquid to a set temperature by adjusting the output of the heater based on the detected temperature of the temperature sensor.
The substrate liquid processing apparatus according to any one of claims 1 to 3 , further comprising. The circulation line connected to the treatment tank and
A pump provided in the circulation line to form a flow of the treatment liquid exiting the treatment tank and returning to the treatment tank through the circulation line.
Further prepare
The temperature sensor is provided at any location in the circulation system including the processing tank and the circulation line.
The substrate liquid processing apparatus according to claim 4 , wherein the heater is provided in the circulation line. The substrate liquid processing apparatus according to claim 5 , wherein the concentration sensor is provided in the circulation line. The treatment tank includes an inner tank in which the substrate is treated by storing the treatment liquid and immersing the substrate in the stored treatment liquid, and an outer tank receiving the treatment liquid overflowing from the inner tank. The substrate liquid processing apparatus according to any one of claims 1 to 6 . The substrate liquid treatment apparatus according to claim 7 , wherein the concentration adjusting unit is configured to add the chemical solution component or the diluted solution to the treatment liquid in the outer tank. A treatment tank in which the substrate is treated by storing the treatment liquid in a boiling state and immersing the substrate in the stored treatment liquid.
A concentration sensor that detects the concentration of the drug solution component contained in the treatment solution, and
Based on the concentration detected by the concentration sensor, the chemical solution component is added to the treatment solution or a diluted solution is added to adjust the concentration of the chemical solution component contained in the treatment solution to the set concentration. Concentration adjustment unit and
A head pressure sensor that detects the head pressure of the treatment liquid in the treatment tank, and
A concentration setting value correction calculation unit that corrects the set concentration given to the concentration adjustment unit based on the detection value of the head pressure sensor, and a concentration setting value correction calculation unit.
A temperature sensor that detects the temperature of the treatment liquid and
A temperature adjusting unit that adjusts the temperature of the processing liquid to a set temperature by adjusting the output of the heater based on the detected temperature of the temperature sensor.
A control unit that generates an alarm warning that an abnormality may have occurred in the head pressure sensor when the temperature of the treatment liquid detected by the temperature sensor is not stable at the detected temperature.
A substrate liquid processing device equipped with . The circulation line connected to the treatment tank and
A pump provided in the circulation line to form a flow of the treatment liquid exiting the treatment tank and returning to the treatment tank through the circulation line.
Further prepare
The temperature sensor is provided at any location in the circulation system including the processing tank and the circulation line.
The substrate liquid processing apparatus according to claim 9 , wherein the heater is provided in the circulation line. The substrate liquid processing apparatus according to claim 10 , wherein the temperature sensor is provided at the outlet of the heater of the circulation line. The substrate liquid treatment apparatus according to any one of claims 1 to 11, wherein the treatment liquid is an aqueous phosphoric acid solution, the chemical liquid component is phosphoric acid, and the diluted liquid is pure water.

Images