JP2020177944A - Silicon wafer etching method and etching apparatus - Google Patents

Abstract

To provide a silicon wafer etching method which enables successive processes while keeping a constant etching rate and retaining a fixed post-etching wafer shape.SOLUTION: A silicon wafer etching method comprises: a spin etching step of performing an acid etching in a state in which a supply range of an acid etchant is enlarged to a whole area by turning around a silicon wafer while supplying the acid etchant to the surface or backside of a silicon wafer through a supply nozzle; a step of repeatedly executing the spin etching step, thereby successively processing a plurality of silicon wafers, collecting the acid etchant used during the successive processes and bringing it back into an etchant tank to use it as the acid etchant again; and a liquid discard/supply step of discarding a predetermined amount of the acid etchant thus collected and supplying an additional acid etchant of a predetermined amount; and using the acid etchant after the discard/supply step for the spin etching step.SELECTED DRAWING: Figure 1

Description

The present invention relates to an etching method and an etching apparatus for a silicon wafer.

In the manufacturing process of a silicon wafer, a wafer sliced thinly from a single crystal ingot state is generally flattened through chamfering and grinding. At this time, various large and small scratches and processing strains due to the above processing are introduced on the front and back surfaces of the wafer, and if these are manifested in the subsequent process, it may cause a serious quality problem.

Therefore, usually, an etching process is performed to remove these scratches and processing strains. As an etching method, a batch method in which the front and back surfaces of a plurality of wafers are processed at the same time and a spin etching method in which the front surface and the back surface of the wafer are sequentially processed by a single sheet are known (see Patent Document 1). Further, there are two means depending on the purpose, one is treatment with an acid etching solution and the other is treatment with an alkaline etching solution. For example, in the case of acid etching, a mixed acid containing fluorine and nitric acid whose concentration is appropriately adjusted. Is generally used.

Japanese Unexamined Patent Publication No. 2007-53178

When acid etching is performed by the spin etching method, the used etching solution is usually recovered and used again as the etching solution, so that the concentrations of fluoroacid and nitric acid contained in the etching solution continuously change according to the number of processed sheets. As a result, the etching rate also changes continuously, so there is a problem that a constant processing amount cannot be maintained. Further, in reality, not only the etching rate but also the take-off distribution in the wafer surface changes according to the number of processed sheets, so that there is a problem that the wafer shape after etching cannot be maintained constant.

Conventionally, phosphoric acid supplementation is often performed as a countermeasure to this problem, but although the etching rate is maintained by this method, it is not possible to cope with the change in the wafer shape after the etching process. Therefore, when the shape change becomes large, it is unavoidable to suspend the processing and replace the etching solution.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide an etching method for a silicon wafer capable of continuous processing while maintaining a constant etching rate and a wafer shape after etching processing. To do.

In order to solve the above object, the present invention is to rotate the silicon wafer while supplying the acid etching solution stored in the etching solution tank through a supply nozzle to the front surface and / or the back surface of the silicon wafer. A silicon wafer etching method including a spin etching step of expanding the supply range of the etching solution to the entire surface and / or the back surface of the silicon wafer and performing acid etching.
By repeating the spin etching process, a plurality of silicon wafers can be continuously processed.
During the continuous processing, the acid etching solution used in the spin etching step is recovered and returned to the etching solution tank to be used as the acid etching solution again.
It includes a drainage / liquid supply step of draining a predetermined amount of the recovered acid etching solution and further supplying a predetermined amount of the new acid etching solution.
Provided is an etching method for a silicon wafer, characterized in that the acid etching solution after the drainage / liquid supply step is used in the spin etching step.

In such a silicon wafer etching method, the amount of Si dissolved in the acid etching solution is increased by performing the acid etching of the spin etching method while draining and supplying the liquid, and the acid etching solution resulting from this. Since the change in kinematic viscosity can be prevented, a constant etching rate and a wafer shape after processing can be obtained even during continuous processing.

At this time, in the drainage / liquid supply step, it is preferable to determine the amount of the drainage and the amount of the liquid to be supplied based on the amount of Si dissolved in the acid etching solution after the recovery.

With such a method, it is possible to more reliably prevent an increase in the amount of Si dissolved and a change in the kinematic viscosity of the acid etching solution due to the increase.

Further, in the drainage / liquid supply step, it is preferable that the amount of the drainage and the amount of the liquid supply are the same.

With such a method, the amount of Si dissolved can be kept constant, so that the change in the kinematic viscosity of the acid etching solution can be more reliably prevented.

Further, as the acid etching solution, it is preferable to use a mixed solution containing phosphoric acid and nitric acid, or a mixed solution in which at least one of acetic acid, phosphoric acid and sulfuric acid is added thereto.

Such a mixed solution can be suitably used for spin etching of a silicon wafer.

Further, the present invention provides a supply nozzle for supplying an acid etching solution stored in an etching solution tank to the front surface and / or the back surface of a silicon wafer.
By holding and rotating the silicon wafer, the supply range of the acid etching solution is expanded to the entire front surface and / or the back surface of the silicon wafer to perform acid etching.
An etching apparatus having a recovery mechanism for recovering the acid etching solution used in the acid etching and returning it to the etching solution tank.
A drainage mechanism for draining a predetermined amount of the acid etching solution from the etching solution tank,
Provided is an etching apparatus characterized in that the etching solution tank is provided with a liquid supply mechanism for supplying a predetermined amount of the acid etching solution.

In the etching apparatus of the present invention, the amount of Si dissolved in the acid etching solution can be increased and the amount of Si dissolved in the acid etching solution can be increased by performing acid etching by the spin etching method while discharging and supplying the liquid by the liquid draining mechanism and the liquid supply mechanism. Since it is possible to prevent a change in the kinematic viscosity of the acid etching solution due to this, it is possible to obtain a constant etching rate and a wafer shape after processing even during continuous processing.

In the silicon wafer etching method and etching apparatus of the present invention, the amount of Si dissolved in the acid etching solution is increased by performing acid etching by the spin etching method while draining and supplying the liquid, and the acid resulting from this. Since it is possible to prevent changes in the kinematic viscosity of the etching solution, it is possible to obtain a constant etching rate and a wafer shape after processing even during continuous processing.

It is a schematic diagram of one Embodiment of the etching apparatus of this invention which connected the liquid supply / drainage mechanism. It is a flow chart which shows one Embodiment by the etching method of the silicon wafer of this invention. It is a figure which shows the transition of the etching rate when the spin etching process is repeated and continuous processing is performed while draining and supplying liquid. It is a figure which shows the transition of the Si dissolution amount at the time of continuous processing by repeating a spin etching process while draining and supplying liquid. It is a figure which shows the change of the wafer shape after processing when the spin etching process is repeated and continuous processing is performed while draining and supplying liquid. It is a figure which shows the transition of the etching rate at the time of repeating continuous processing of spin acid etching without draining and supplying liquid. It is a figure which shows the transition of the Si dissolution amount at the time of repeating continuous processing of spin acid etching without draining and supplying liquid. It is a figure which shows the change of the wafer shape after processing at the time of continuous processing by repeating spin acid etching without draining and supplying liquid.

As described above, when acid etching is performed by the spin etching method, the used etching solution is usually recovered and used again as the etching solution. Therefore, the etching rate and the distribution of the allowance in the wafer surface depend on the number of processed sheets in continuous machining. There was a problem that it changed.

As a result of diligent research, the present inventor changed the kinematic viscosity of the acid etching solution when the amount of Si dissolved in the acid etching solution changed. Therefore, in the spin etching method acid etching in which the fluid characteristics of the etching solution cannot be ignored, the wafer surface It was found that the etching rate distribution in the inside changes, and as a result, the processed shape of the wafer after etching changes.

Therefore, in order to keep the shape quality after processing constant by acid etching of the spin etching method, the wafer after etching is prevented from increasing the amount of Si dissolved in the acid etching solution, and at the same time, the component concentration of the acid etching solution is maintained. We have developed a spin-type acid etching method and an etching device that can maintain a constant shape and etching rate.

That is, in the present invention, the supply range of the acid etching solution is increased by rotating the silicon wafer while supplying the acid etching solution stored in the etching solution tank through the supply nozzle to the front surface and / or the back surface of the silicon wafer. A method for etching a silicon wafer, which comprises a spin etching step of performing acid etching by enlarging the entire surface and / or the back surface of the silicon wafer.
By repeating the spin etching process, a plurality of silicon wafers can be continuously processed.
During the continuous processing, the acid etching solution used in the spin etching step is recovered and returned to the etching solution tank to be used as the acid etching solution again.
It includes a drainage / liquid supply step of draining a predetermined amount of the recovered acid etching solution and further supplying a predetermined amount of the new acid etching solution.
This is a silicon wafer etching method, characterized in that the acid etching solution after the drainage / liquid supply step is used in the spin etching step.

Further, the present invention provides a supply nozzle for supplying an acid etching solution stored in an etching solution tank to the front surface and / or the back surface of a silicon wafer.
By holding and rotating the silicon wafer, the supply range of the acid etching solution is expanded to the entire front surface and / or the back surface of the silicon wafer to perform acid etching.
An etching apparatus having a recovery mechanism for recovering the acid etching solution used in the acid etching and returning it to the etching solution tank.
A drainage mechanism for draining a predetermined amount of the acid etching solution from the etching solution tank,
The etching apparatus is provided with a liquid supply mechanism for supplying a predetermined amount of the new acid etching liquid to the etching liquid tank.

With such a silicon wafer etching method and etching apparatus, the amount of Si dissolved in the acid etching solution is increased by performing acid etching by the spin etching method while draining and supplying the liquid, and the acid resulting from this. Since it is possible to prevent changes in the kinematic viscosity of the etching solution, it is possible to obtain a constant etching rate and a wafer shape after processing even during continuous processing.

Hereinafter, the present invention will be described in detail, but the present invention is not limited thereto.

FIG. 1 is a schematic view of an embodiment of an etching apparatus of the present invention in which a liquid supply / drainage mechanism is connected. Specifically, for example, it is possible to connect the liquid supply / drainage mechanism to the spin etcher MSE-7000EL-MH manufactured by Sanmasu Semiconductor Industry Co., Ltd., which is used in the spin etching method.

The etching apparatus of the present invention has an etching solution tank for storing an acid etching solution, a supply nozzle for supplying the acid etching solution to the front surface and / or the back surface of the silicon wafer, and a stage for holding and rotating the silicon wafer. , A recovery mechanism for collecting the acid etching solution and returning it to the etching solution tank, a draining mechanism for draining the acid etching solution from the etching solution tank, and a mechanism for supplying a new acid etching solution to the etching solution tank. It is equipped with a liquid supply mechanism.

The etching apparatus 100 of the present invention can be composed of an etching processing unit 14 and an etching solution supply unit 13, for example, as shown in FIG.

The etching processing unit 14 can include a vacuum suction stage (stage) 2, a supply nozzle 3, and an etching solution recovery cup 19. In this case, the supply nozzle 3 may be provided not only on the front surface side but also on the back surface side so that both surfaces of the wafer can be etched at the same time.

The etching solution supply unit 13 transfers the acid etching solution from the etching solution tank 6, the liquid feeding pump 18 that sends the acid etching solution from the etching solution tank 6 to the etching processing section, and the etching solution recovery cup 19 to the etching solution tank 6. A recovery mechanism 21 having a recovery pump 20 for recovery and a liquid drainage / liquid supply mechanism 17 can be provided.

The etching solution tank 6 contains the acid etching solution 8, and the acid etching solution in which a predetermined amount of Si is dissolved by the recovered acid etching solution is contained. The drainage / liquid supply mechanism 17 includes a liquid supply mechanism 22 including a liquid supply tank 11 and a liquid supply pump 12 for sending the acid etching liquid from the liquid supply tank 11 to the etching liquid tank 6, and a drainage treatment unit 16. It can be composed of a drainage mechanism 23 including a drainage pump 15 that extracts the acid etching liquid from the etching liquid tank 6 of the etching liquid supply unit 13 and sends the liquid to the drainage treatment unit 16. The acid etching solution having the same component concentration as the acid etching solution 8 contained in the etching solution tank 6 in the state where Si is not dissolved may be put into the liquid supply tank 11.

The silicon wafer 1 is horizontally installed in the center of the vacuum suction stage 2 with the front surface or the back surface facing up, and can be held by vacuum suction on the vacuum suction stage 2 connected to the vacuum source 10.

The vacuum suction stage 2 can be rotated in the θ direction in the figure with the center of the vacuum suction stage 2 as the rotation axis by a rotation unit having a θ-axis motor and a θ spindle (not shown) below the stage.

Next, the etching method for the silicon wafer of the present invention will be described by taking the case of using the etching apparatus 100 shown in FIG. 1 as an example. FIG. 2 illustrates a processing flow by the etching method of the silicon wafer of the present invention.

In the silicon wafer etching method of the present invention, the silicon wafer is rotated while supplying the acid etching solution stored in the etching solution tank through a supply nozzle to the front surface and / or the back surface of the silicon wafer (step 1 in FIG. 2). It includes a spin etching step (etching process, step 2 in FIG. 2) in which the supply range of the acid etching solution is expanded over the entire surface of the silicon wafer to perform acid etching. The acid etching solution can be a mixed solution containing phosphoric acid and nitric acid, but acetic acid, sulfuric acid, or phosphoric acid may be appropriately combined and mixed therewith. Such a mixed solution can be suitably used for spin etching of a silicon wafer. The mixing ratio may be an acid etching solution in which, for example, 1 to 80% of phosphoric acid and 10 to 80% of nitric acid are mixed in mass ratio, but acetic acid is, for example, 10 to 30%, and sulfuric acid is, for example, 10 to 10% by mass. 25% and, for example, 10 to 50% of phosphoric acid may be mixed in an arbitrary ratio.

At this time, as shown in FIG. 1, the acid etching solution 8 is supplied from the etching solution tank 6 of the etching solution supply unit 13 to the supply nozzle 3 above the vacuum adsorption stage 2 via the liquid feed pump 18, and is vacuum-adsorbed. The acid etching solution 8 can be supplied to the silicon wafer 1 held and rotating on the stage 2. While the acid etching solution 8 is being supplied, the supply nozzle 3 linearly reciprocates in the radial direction of the silicon wafer 1 through the center of the silicon wafer 1 as shown by an arrow 4 (movement direction of the supply nozzle) in FIG. It is common to do.

Further, in the silicon wafer etching method of the present invention, a plurality of silicon wafers are continuously processed by repeating the spin etching process. Further, during the continuous processing, a step of recovering the acid etching solution used in the spin etching step and returning the acid etching solution to the etching solution tank to make the acid etching solution again is included (step 3 in FIG. 2).

The acid etching solution 8 supplied onto the silicon wafer 1 moves on the silicon wafer 1 following the rotation of the silicon wafer 1, becomes droplets 5 from the outer peripheral portion of the silicon wafer 1, and is discharged from the wafer.

The discharged droplet 5 enters the etching solution recovery cup 19 and can be collected in the etching solution tank 6 by the recovery pump 20. The recovered acid etching solution collected in the etching solution tank 6 is again referred to as the acid etching solution 8.

When the etching process is completed after satisfying the predetermined etching allowance, the supply of the acid etching solution 8 from the etching solution tank 6 is stopped (step 4 in FIG. 2), and water 9 is supplied from the water supply source 7 to the supply nozzle 3. Then, the water 9 can be supplied onto the silicon wafer 1 held and rotated on the vacuum suction stage 2 (rinse, step 6 in FIG. 2).

The water 9 supplied onto the silicon wafer 1 moves on the silicon wafer 1 following the rotation of the silicon wafer 1, and replaces the acid etching solution 8 remaining on the silicon wafer 1 with water 9 of the silicon wafer 1. The droplets 5 are discharged from the outer peripheral portion.

Further, the method for manufacturing a silicon wafer of the present invention is a drainage / liquid supply step (step of FIG. 2) in which a predetermined amount of the recovered acid etching solution is drained and a predetermined amount of a new acid etching solution is further supplied. 5) is included. Then, the acid etching liquid after the drainage / liquid supply step is used in the spin etching step in the continuous processing of a plurality of silicon wafers.

After the supply of the acid etching solution 8 is stopped, an appropriate amount of the recovered acid etching solution is discharged from the etching solution tank 6 to the drainage treatment unit 16 via the drainage pump 15 of the drainage / liquid supply mechanism 17. be able to. After that, an appropriate amount of new acid etching liquid can be supplied from the liquid supply tank 11 of the drainage / liquid supply mechanism 17 to the etching liquid tank 6 via the liquid supply pump 12. Further, when the replacement of the acid etching solution 8 on the silicon wafer 1 with water is completed, the supply of water 9 from the water supply source 7 is stopped, and the silicon wafer 1 is rotated at high speed to scatter all the water on the silicon wafer 1. , A dried silicon wafer 1 can be obtained (rinse / dry, step 6 in FIG. 2).

At this time, in the drainage / liquid supply step, it is preferable to determine the amount of liquid to be drained and the amount of liquid to be supplied based on the amount of Si dissolved in the acid etching solution after recovery. The Si dissolution amount can be calculated from a predetermined etching allowance of the silicon wafer, but is not particularly limited, and can also be obtained by a mechanism or the like provided in an etching solution tank or the like for measuring the Si dissolution amount. In this way, the amount of Si dissolved in the acid etching solution is increased by draining and supplying an appropriate amount of liquid based on the amount of Si dissolved obtained by calculating the amount of Si increased by melting by etching. It is possible to more reliably prevent the increase in the kinematic viscosity of the acid etching solution and the resulting change in the kinematic viscosity of the acid etching solution.

Further, in order to keep the amount of Si dissolved constant, it is possible to drain a certain amount of the recovered acid etching solution in which Si is dissolved and then supply a new acid etching solution in the same amount in which Si is not dissolved. preferable. In this way, the Si dissolution amount can be returned to the Si dissolution amount before being increased by etching.

Further, the drainage / liquid supply step may be performed during continuous machining of a plurality of silicon wafers, and the timing is not particularly limited, but a constant Si dissolution amount is maintained for each spin etching step of the etching process. As a result, the shape quality after processing can be made constant. For example, the amount of Si dissolved in the acid etching solution is kept constant by draining and supplying an amount of liquid corresponding to the etching allowance each time one etching process is performed. Since the consumption of phosphoric acid and nitric acid is proportional to the amount of Si dissolved, keeping the amount of Si dissolved in the acid etching solution constant by draining and supplying liquid means that the concentration of fluorine and nitric acid in the same acid etching solution are kept constant. Equivalent to keeping the concentration constant.

The amount of Si dissolved in acid etching by the spin etching method is preferably 12 g / L or less. Within such a range, the change in the characteristics of the fluid does not become too large, and the shape of the wafer after processing in the collision jet area formed directly under the nozzle for supplying the acid etching solution becomes good.

The etching allowance per silicon wafer is usually preferably 3 to 8 μm, which is an amount capable of removing the processing alteration layer introduced into the surface of the silicon wafer by the lapping process or the surface grinding process, which is the previous process, as the etching allowance for one surface. .. If the amount of drainage / supply based on the amount of Si molars calculated from this etching allowance is performed every time during rinsing after, for example, the spin etching process, continuous etching processing is performed while keeping the amount of Si dissolved at a constant amount. This makes it possible to more reliably perform continuous processing while maintaining the etching rate and the shape after etching constant.

Hereinafter, the present invention will be described in more detail with reference to Examples and Comparative Examples, but the present invention is not limited to the following Examples.

[Example]
Using the etching apparatus shown in FIG. 1, 100 silicon wafers were continuously etched according to the processing flow of FIG. 2 while draining and supplying the acid etching solution in the etching solution tank. At this time, the drainage / liquid supply step was performed every time the spin etching step of one silicon wafer was completed. The acid etching solution used in the examples was a mixed solution of fluorine and nitric acid, and the mixing ratio was mass%, fluorine was 4%, and nitric acid was 47% (the balance of less than 100% was water. ). As the first acid etching solution, one having a Si dissolution amount of 10 g / L was used, and as a new acid etching solution to be supplied, an acid etching solution containing no Si atom was used. The amounts of drainage and supply were the same, and were determined based on the amount of Si dissolved obtained from the etching allowance.

FIGS. 3, 4 and 5 show changes in the etching rate, changes in the amount of Si dissolved, and changes in the wafer shape after processing when the spin etching process is repeated and continuously processed while draining and supplying liquid, respectively.

[Comparison example]
Using a commonly used etching apparatus that does not have a drainage mechanism and a liquid supply mechanism, etching of 100 silicon wafers was continuously performed without draining or supplying liquid. The acid etching solution used in the comparative example was a mixed solution of fluorine and nitric acid, and the mixing ratio was mass%, fluorine was 4%, and nitric acid was 47% (the balance of less than 100% was water. ). As the first acid etching solution, a Si dissolution amount of 10 g / L was used, and continuous processing was started.

FIGS. 6, 7 and 8 show changes in the etching rate, changes in the amount of Si dissolved, and changes in the wafer shape after processing when spin acid etching is repeated and continuously processed without draining and supplying liquid, respectively. ..

As shown in FIGS. 3, 4, and 5, when the liquid is drained and supplied, the amount of Si dissolved is maintained almost constant, and the etching rate variation during continuous processing of 100 sheets is within ± 7%. there were. The shape of the wafers after processing was the same as the flatness TTV (Total Tickness Variation) of the first, 50th, and 100th wafers processed. As shown in FIGS. 6, 7, and 8, when the liquid was not drained or supplied, the etching rate decreased monotonically as the amount of Si dissolved increased monotonically, and the etching rate during processing of 100 sheets. Was about 70% of the first sheet. The shape of the wafer after processing changed as the number of processed sheets increased, and the TTV after processing 100 sheets deteriorated 2.6 times as much as that of the first sheet.

From the above, by using the silicon wafer etching method and etching apparatus of the present invention, it is possible to obtain a constant etching rate and a wafer shape after processing even during continuous processing by draining and supplying liquid. Shown.

The present invention is not limited to the above embodiment. The above-described embodiment is an example, and any object having substantially the same configuration as the technical idea described in the claims of the present invention and exhibiting the same effect and effect is the present invention. Is included in the technical scope of.

100 ... Etching device,
1 ... Silicon wafer, 2 ... Stage (vacuum suction stage),
3 ... Supply nozzle, 4 ... Supply nozzle movement direction, 5 ... Droplet,
6 ... Etching liquid tank, 7 ... Water supply source, 8 ... Acid etching liquid,
9 ... water, 10 ... vacuum source, 11 ... liquid supply tank, 12 ... liquid supply pump,
13 ... Etching liquid supply unit, 14 ... Etching processing unit,
15 ... Drainage pump, 16 ... Drainage processing unit, 17 ... Drainage / liquid supply mechanism,
18 ... Liquid feed pump, 19 ... Etching liquid recovery cup, 20 ... Recovery pump,
21 ... Recovery mechanism, 22 ... Liquid supply mechanism, 23 ... Liquid drainage mechanism.

Claims (5)

By rotating the silicon wafer while supplying the acid etching solution stored in the etching solution tank through a supply nozzle to the front surface and / or the back surface of the silicon wafer, the supply range of the acid etching solution is adjusted to the surface and / or the surface of the silicon wafer. / Or a silicon wafer etching method including a spin etching step in which the entire back surface is enlarged and acid-etched.
By repeating the spin etching process, a plurality of silicon wafers can be continuously processed.
During the continuous processing, the acid etching solution used in the spin etching step is recovered and returned to the etching solution tank to be used as the acid etching solution again.
It includes a drainage / liquid supply step of draining a predetermined amount of the recovered acid etching solution and further supplying a predetermined amount of the new acid etching solution.
A method for etching a silicon wafer, characterized in that the acid etching solution after the drainage / liquid supply step is used in the spin etching step. The first aspect of claim 1, wherein in the drainage / liquid supply step, the amount of the liquid to be drained and the amount of the liquid to be supplied are determined based on the amount of Si dissolved in the acid etching solution after recovery. Etching method for silicon wafers. The method for etching a silicon wafer according to claim 1 or 2, wherein in the drainage / liquid supply step, the amount of the liquid to be drained and the amount of the liquid to be supplied are the same. Claims 1 to 3 are characterized in that, as the acid etching solution, a mixed solution containing phosphoric acid and nitric acid, or a mixed solution in which at least one of acetic acid, phosphoric acid, and sulfuric acid is added thereto is used. The method for etching a silicon wafer according to any one of the above. A supply nozzle for supplying the acid etching solution stored in the etching solution tank to the front surface and / or the back surface of the silicon wafer, and
By holding and rotating the silicon wafer, the supply range of the acid etching solution is expanded to the entire front surface and / or the back surface of the silicon wafer to perform acid etching.
An etching apparatus having a recovery mechanism for recovering the acid etching solution used in the acid etching and returning it to the etching solution tank.
A drainage mechanism for draining a predetermined amount of the acid etching solution from the etching solution tank,
An etching apparatus including a liquid supply mechanism for supplying a predetermined amount of the acid etching liquid to the etching liquid tank.

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