WO2014178289A1 - 銅露出基板の洗浄方法および洗浄システム - Google Patents
銅露出基板の洗浄方法および洗浄システム Download PDFInfo
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- WO2014178289A1 WO2014178289A1 PCT/JP2014/060902 JP2014060902W WO2014178289A1 WO 2014178289 A1 WO2014178289 A1 WO 2014178289A1 JP 2014060902 W JP2014060902 W JP 2014060902W WO 2014178289 A1 WO2014178289 A1 WO 2014178289A1
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- Prior art keywords
- water
- copper
- hydrogen peroxide
- substrate
- cleaning
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- C—CHEMISTRY; METALLURGY
- C23—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
- C23G—CLEANING OR DE-GREASING OF METALLIC MATERIAL BY CHEMICAL METHODS OTHER THAN ELECTROLYSIS
- C23G1/00—Cleaning or pickling metallic material with solutions or molten salts
- C23G1/02—Cleaning or pickling metallic material with solutions or molten salts with acid solutions
- C23G1/10—Other heavy metals
- C23G1/103—Other heavy metals copper or alloys of copper
-
- C—CHEMISTRY; METALLURGY
- C23—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
- C23G—CLEANING OR DE-GREASING OF METALLIC MATERIAL BY CHEMICAL METHODS OTHER THAN ELECTROLYSIS
- C23G1/00—Cleaning or pickling metallic material with solutions or molten salts
- C23G1/14—Cleaning or pickling metallic material with solutions or molten salts with alkaline solutions
- C23G1/20—Other heavy metals
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/02—Manufacture or treatment of semiconductor devices or of parts thereof
- H01L21/02041—Cleaning
- H01L21/02057—Cleaning during device manufacture
- H01L21/02068—Cleaning during device manufacture during, before or after processing of conductive layers, e.g. polysilicon or amorphous silicon layers
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/67—Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereof; Apparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components ; Apparatus not specifically provided for elsewhere
- H01L21/67005—Apparatus not specifically provided for elsewhere
- H01L21/67011—Apparatus for manufacture or treatment
- H01L21/67017—Apparatus for fluid treatment
- H01L21/67028—Apparatus for fluid treatment for cleaning followed by drying, rinsing, stripping, blasting or the like
- H01L21/6704—Apparatus for fluid treatment for cleaning followed by drying, rinsing, stripping, blasting or the like for wet cleaning or washing
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- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F1/00—Treatment of water, waste water, or sewage
- C02F1/20—Treatment of water, waste water, or sewage by degassing, i.e. liberation of dissolved gases
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F1/00—Treatment of water, waste water, or sewage
- C02F1/42—Treatment of water, waste water, or sewage by ion-exchange
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F1/00—Treatment of water, waste water, or sewage
- C02F1/44—Treatment of water, waste water, or sewage by dialysis, osmosis or reverse osmosis
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F1/00—Treatment of water, waste water, or sewage
- C02F1/68—Treatment of water, waste water, or sewage by addition of specified substances, e.g. trace elements, for ameliorating potable water
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2103/00—Nature of the water, waste water, sewage or sludge to be treated
- C02F2103/02—Non-contaminated water, e.g. for industrial water supply
- C02F2103/04—Non-contaminated water, e.g. for industrial water supply for obtaining ultra-pure water
Definitions
- the present invention relates to a method for treating a copper exposed substrate.
- the present invention relates to a method and a cleaning system used for cleaning a substrate on which copper or a copper compound is exposed.
- substrates to be processed include semiconductor wafers on which semiconductor integrated circuits are formed, substrates for liquid crystal display devices, substrates for plasma displays, substrates for field emission displays, substrates for optical disks, substrates for magnetic disks, and magneto-optical disks. Substrates, photomask substrates, ceramic substrates and the like are included.
- cleaning is performed for the purpose of removing chemicals, fine particles, organic substances, metals, etc. adhering to the surface of the object to be processed such as wafers and substrates, thereby achieving a high degree of cleanliness.
- This is important for maintaining product quality and improving yield.
- a chemical solution such as a sulfuric acid / hydrogen peroxide solution mixed solution or a hydrofluoric acid solution
- cleaning using ultrapure water is performed.
- the number of cleanings has increased due to miniaturization of semiconductor devices, diversification of materials, and complexity of processes.
- a metal wiring serving as a first wiring layer is formed on the substrate, the metal wiring is filled with an insulating material, and the surface of the insulating material covering the metal wiring is flattened by CMP, and then flattened. Then, the procedure of forming a metal wiring serving as a second wiring layer on the surface, filling the metal wiring with an insulating material, and flattening the surface of the insulating material by CMP is repeated. In such a process, the substrate is cleaned every time the polishing step is completed.
- the pretreatment system is a process for removing suspended substances and colloidal substances contained in raw water by, for example, coagulation sedimentation or sand filtration.
- the primary pure water system uses, for example, an ion exchange resin or a reverse osmosis (RO) membrane to remove the ionic components and organic components of the raw water from which the suspended substances have been removed by the pretreatment system. This is a process for obtaining water. As shown in FIG.
- the sub-system includes a continuous UV oxidation device (UV), non-regenerative ion exchange device (for example, cartridge polisher (CP)), membrane separation device (for example, ultrafiltration device (UF)), and the like.
- UV UV
- non-regenerative ion exchange device for example, cartridge polisher (CP)
- membrane separation device for example, ultrafiltration device (UF)
- ultrapure water by further increasing the purity of the primary pure water obtained by the primary pure water system using the water flow line.
- the ultrapure water supplied from the subsystem is supplied to substrate cleaning devices such as batch-type substrate cleaning devices and single-wafer substrate cleaning devices, and substrate processing devices such as CMP devices, and unused ultrapure water is supplied to the subsystem inlet. Or it is returned to the primary pure water system for reuse.
- the ultrapure water obtained in this way is used as cleaning water for a semiconductor substrate, if the dissolved oxygen concentration in the cleaning water is high, a natural oxide film is likely to be formed on the wafer surface by the cleaning water. This may hinder precise control of the thickness and quality of the gate oxide film, and may increase contact resistance of contact holes, vias, plugs, and the like.
- a wiring metal such as tungsten or copper is exposed on the surface of the substrate that is cleaned after the polishing step in the multilayer wiring formation process. Since this wiring metal is a metal that is easily corroded by oxygen dissolved in the cleaning water, the wiring is subject to oxidative corrosion during the cleaning of the substrate, which may deteriorate the performance of the integrated circuit element formed from this substrate.
- a membrane deaerator may be installed in the subsystem for the purpose of removing gas components dissolved in ultrapure water, especially oxygen.
- a membrane deaerator is often installed between an ultraviolet oxidation device and a non-regenerative ion exchange device (FIG. 3), or between a non-regenerative ion exchange device and a membrane separation device (FIG. 4).
- FOG. 3 non-regenerative ion exchange device
- FIG. 4 membrane separation device
- impurities (ions) eluted from the membrane deaerator can be removed by a non-regenerative ion exchanger.
- a very small amount of gas components generated by the non-regenerative ion exchange device can be removed by the membrane degassing device.
- Patent Document 1 As a further countermeasure, as described in Patent Document 1, a method for reducing dissolved oxygen in water by adding an inert gas to degassed ultrapure water has been proposed. Patent Document 1 also employs a method of replacing the atmosphere near the surface of the substrate to be cleaned with an inert gas. Patent Document 2 describes a method of suppressing oxidation of a substrate by dissolving hydrogen gas in ultrapure water.
- water is also decomposed and removed by irradiating water with ultraviolet rays using an ultraviolet oxidizer, so that water molecules are also oxidized by this ultraviolet irradiation, producing hydrogen peroxide, an oxidizing substance. Is done. That is, the ultrapure water contains hydrogen peroxide.
- Patent Document 2 As a method of removing hydrogen peroxide in water, a method of removing hydrogen peroxide in water using a platinum group metal catalyst such as palladium as described in Patent Document 2 is known.
- Patent Document 3 by contacting a catalyst in which a platinum group metal is supported on a monolithic organic porous anion exchanger and a raw water containing hydrogen peroxide, hydrogen peroxide is rapidly and rapidly increased from the raw water.
- a method for efficiently decomposing and removing is presented.
- a platinum group metal catalyst such as palladium
- Patent Document 2 by dissolving hydrogen in advance before passing through the platinum group metal catalyst, It is known that hydrogen peroxide and dissolved oxygen can be removed simultaneously.
- the ultrapure water obtained by the above-mentioned subsystem has impurities removed to the limit, and therefore its specific resistance has reached 18 M ⁇ ⁇ cm or more and has high insulation.
- a substrate such as a semiconductor wafer is washed using such ultra-pure water having a high specific resistance
- the substrate is charged by friction, causing adhesion of fine particles due to electrostatic action and electrostatic breakdown of the element due to discharge.
- the specific resistance of water is lowered by adding high purity carbon dioxide to ultrapure water, and this carbon dioxide added water (that is, carbonated water) is used as a cleaning liquid. The method is taken.
- carbonated water has properties different from ultrapure water in that the specific resistance is low and the pH is weakly acidic due to the high carbonate concentration. Therefore, for example, when carbonated water is used as the cleaning water, it is known that a problem that copper exposed on the substrate surface is dissolved occurs. As the pattern dimensions of the integrated circuit element are further miniaturized, the thickness of the wiring is also becoming thinner, and there is a concern in the future that slight corrosion of the wiring will deteriorate the performance of the integrated circuit element.
- the present inventors analyzed a cleaning test of a copper-exposed substrate with carbonated water.
- hydrogen peroxide contained in carbonated water contributed to the progress of copper corrosion. I found that.
- hydrogen peroxide was generated in water by an ultraviolet oxidizer, and it was found for the first time that this caused corrosion.
- the present invention is based on the above analysis results, and one of its purposes is to prevent the substrate from being charged and to further suppress the corrosion and dissolution of copper exposed on the substrate surface.
- a cleaning method and a cleaning system are provided.
- One embodiment of the present invention relates to a method for cleaning a copper exposed substrate.
- dissolved hydrogen peroxide concentration is suppressed to 2 ⁇ g / L or less, and carbon dioxide is added to produce carbonated water having a specific resistance adjusted to a range of 0.03 to 5.0 M ⁇ ⁇ cm.
- carbonated water is used to clean the substrate with at least copper or a copper compound exposed on the surface.
- Still another aspect relates to a copper exposed substrate cleaning system.
- an ultrapure water production apparatus including an ultraviolet oxidation apparatus that irradiates water with ultraviolet rays and a substrate on which at least copper or a copper compound is exposed are arranged, and a substrate processing solution for cleaning the substrate is supplied. And a processing chamber.
- the concentration of hydrogen peroxide dissolved in water is suppressed to 2 ⁇ g / L or less in the flow path from the ultraviolet oxidation device of the ultrapure water production device to the treatment liquid discharge part of the treatment chamber, and carbon dioxide is added.
- the charging of the substrate can be suppressed, and further, the corrosion and dissolution of copper and copper compounds exposed on the substrate surface with carbonated water can be further suppressed than in the prior art. Therefore, it is possible to provide a substrate processing that hardly degrades the performance of the manufactured integrated circuit element.
- FIG. 2 is a schematic diagram showing an aspect of a test line of Example 1.
- FIG. It is a SEM image of the sample which performed the washing
- Example 6 is a schematic diagram showing an aspect of a test line of Example 2.
- FIG. 6 is a schematic diagram showing an aspect of a test line of Example 5.
- the various embodiments described below use a carbonated water obtained by adding carbon dioxide to ultrapure water produced by a subsystem including an ultraviolet oxidizer to clean a substrate installed in a processing chamber of the substrate processing apparatus.
- the substrate to be cleaned includes a substrate such as a semiconductor wafer in which at least copper or a copper compound is exposed.
- FIG. 5 is a schematic view showing an aspect of the substrate cleaning method according to the first embodiment of the present invention.
- the water outlet of the subsystem and the water inlet of each substrate processing apparatus are connected via a main pipe made of PVC, PFA or the like mainly used in a semiconductor manufacturing line.
- a processing chamber is installed in the substrate processing apparatus 1 (not shown), and cleaning water is supplied.
- a mechanism for holding substrates is installed in the processing chamber, and the mechanism is a single wafer type in which carbonated water is sprayed on a single substrate, or a plurality of substrates are immersed in a tank in which carbonated water is stored. Any of the batch types to be processed.
- the hydrogen peroxide removing device 2 is installed between the UV oxidation device and the non-regenerative ion exchange device of the subsystem shown in FIG. Further, a carbon dioxide supply device 4 is installed in the middle of the pipe 3 that branches from the water outlet of the subsystem and reaches the substrate processing apparatus 1.
- the hydrogen peroxide removal device 2 has a mode in which a platinum group metal catalyst is filled.
- a catalyst unit filled with a palladium catalyst or a catalyst unit in which a palladium catalyst is supported on a monolithic organic porous anion exchanger can be mentioned, and more specific examples of the platinum group metal catalyst will be described later. I will decide.
- the carbon dioxide supply device 4 adds carbon dioxide so that the specific resistance of water (carbonated water) after carbon dioxide addition is 0.03 M ⁇ ⁇ cm to 5.0 M ⁇ ⁇ cm.
- a film dissolution method is preferably used as a means for adding.
- the water obtained by such an embodiment has a hydrogen peroxide concentration reduced to a hydrogen peroxide concentration of 2 ⁇ g / L or less and a specific resistance of 0.03 M ⁇ ⁇ cm to 5.0 M ⁇ ⁇ cm.
- Carbonated water with carbon added When this is supplied to the substrate processing apparatus 1 as cleaning water and used for cleaning the substrate, the dissolution of copper exposed on the substrate surface is compared with carbonated water whose hydrogen peroxide concentration is not suppressed to 2 ⁇ g / L or less. Can be further suppressed. This is based on the evaluation result shown in the Example mentioned later.
- the hydrogen peroxide removal device 2 By installing the hydrogen peroxide removal device 2 at the subsequent stage of the ultraviolet oxidation device, it is possible to remove hydrogen peroxide generated by the ultraviolet oxidation device. In addition, by installing the hydrogen peroxide removing device 2 in front of the non-regenerative ion exchange device, it is possible to remove a very small amount of impurities (ions) eluted from the hydrogen peroxide removing device 2.
- FIG. 6 shows another aspect of the present embodiment.
- the hydrogen peroxide removing device 2 is installed between the ultraviolet oxidizer and the membrane deaerator of the subsystem shown in FIG. As a result, the gas component generated by the hydrogen peroxide removing device 2 can be removed.
- FIG. 7 another aspect of this embodiment is shown in FIG.
- the hydrogen peroxide removing device 2 is installed between the UV oxidation device and the non-regenerative ion exchange device of the subsystem shown in FIG. Since the membrane deaerator is installed at the subsequent stage of the non-regenerative ion exchange device, it is possible to remove gas components generated by the hydrogen peroxide removing device 2 and the non-regenerative ion exchange device.
- the hydrogen peroxide removing apparatus 2 since the hydrogen peroxide removing apparatus 2 is installed inside the subsystem, it is not necessary to install the hydrogen peroxide removing apparatus 2 for each substrate processing apparatus 1, and the cost associated with the installation can be reduced. There is.
- the processing chamber of the substrate processing apparatus 1 it is desirable to fill the processing chamber of the substrate processing apparatus 1 with an inert gas so that the oxygen gas concentration in the processing chamber is 2% or less.
- Nitrogen gas can be suitably used as the inert gas from the viewpoint of economy. This is based on the test results described in the examples.
- the processing chamber of the substrate processing apparatus 1 it is preferable to shield the processing chamber of the substrate processing apparatus 1 from light during the substrate cleaning process. This is based on the test results described in the examples.
- FIG. 8 is a schematic view showing an aspect of the substrate cleaning method according to the second embodiment of the present invention.
- the water outlet of the subsystem and the water inlet of each substrate processing apparatus are connected via a main pipe made of PVC, PFA or the like mainly used in a semiconductor manufacturing line.
- a processing chamber is installed in the substrate processing apparatus 1 (not shown), and cleaning water is supplied.
- a mechanism for holding substrates is installed in the processing chamber, and the mechanism is a single wafer type in which carbonated water is sprayed on a single substrate, or a plurality of substrates are immersed in a tank in which carbonated water is stored. Any of the batch types to be processed.
- the hydrogen supply device 5 and the hydrogen peroxide removal device 2 are installed in this order in the water supply direction between the UV oxidation device and the non-regenerative ion exchange device of the subsystem shown in FIG. Yes. Further, a carbon dioxide supply device 4 is installed in the middle of the pipe 3 that branches from the water outlet of the subsystem and reaches the substrate processing apparatus 1.
- hydrogen is added by the hydrogen supply device 5 and the hydrogen peroxide removing device 2 is passed through, hydrogen reacts with dissolved oxygen in the water to generate water in the hydrogen peroxide removing device 2, so that ultrapure water The dissolved oxygen concentration inside can be further reduced. That is, it becomes possible to remove hydrogen peroxide and oxygen at the same time in the hydrogen peroxide removing device 2.
- the hydrogen peroxide removal device 2 has a mode in which a platinum group metal catalyst is filled.
- a catalyst unit filled with a palladium catalyst or a catalyst unit in which a palladium catalyst is supported on a monolithic organic porous anion exchanger can be mentioned, and more specific examples of the platinum group metal catalyst will be described later. I will decide.
- the hydrogen supply device 5 is not particularly limited as long as it is a method of adding hydrogen to water, but for example, a method of adding a hydrogen gas by adding a hydrogen-dissolving film to the main pipe as shown in FIG. 9 may be used. it can.
- a method of supplying hydrogen water produced by adding hydrogen gas to ultrapure water using a hydrogen-dissolving film to the main pipe can be used.
- a method of taking out cathode water containing hydrogen obtained by electrolyzing ultrapure water using an electrolytic cell and supplying it to the main pipe can also be used.
- the hydrogen to be added it is desirable for removing dissolved oxygen to add hydrogen so that the hydrogen concentration becomes 1 or more with respect to the dissolved oxygen concentration 8.
- the carbon dioxide supply device 4 adds carbon dioxide so that the specific resistance of water (carbonated water) after carbon dioxide addition is 0.03 M ⁇ ⁇ cm to 5.0 M ⁇ ⁇ cm.
- a film dissolution method is preferably used as a means for adding.
- the water obtained by such an embodiment is reduced so that the hydrogen peroxide concentration is 2 ⁇ g / L or less, the dissolved oxygen concentration is 2 ⁇ g / L or less, and the specific resistance is 0.03 M ⁇ ⁇ cm to 5.0 M ⁇ ⁇ cm. It becomes carbonated water to which carbon dioxide has been added.
- the dissolution of copper exposed on the substrate surface is compared with carbonated water whose hydrogen peroxide concentration is not suppressed to 2 ⁇ g / L or less. Can be further suppressed. This is based on the evaluation result shown in the Example mentioned later.
- FIG. 12 shows another aspect of the present embodiment.
- the membrane deaerator 6 is installed in the middle of returning unused ultrapure water to the subsystem inlet or the primary pure water system. This membrane deaerator 6 is installed to prevent the added hydrogen from accumulating with the circulation of ultrapure water.
- the hydrogen supply device 5 and the hydrogen peroxide removal device 2 are installed inside the subsystem, it is necessary to install the hydrogen supply device 5 and the hydrogen peroxide removal device 2 for each substrate processing apparatus 1. There is an advantage that the cost related to installation can be reduced.
- the processing chamber of the substrate processing apparatus 1 it is desirable to fill the processing chamber of the substrate processing apparatus 1 with an inert gas so that the oxygen gas concentration in the processing chamber is 2% or less.
- Nitrogen gas can be suitably used as the inert gas from the viewpoint of economy. This is based on the test results described in the examples.
- the processing chamber of the substrate processing apparatus 1 it is preferable to shield the processing chamber of the substrate processing apparatus 1 from light during the substrate cleaning process. This is based on the test results described in the examples.
- FIG. 13 is a schematic view showing an aspect of the substrate cleaning method according to the third embodiment of the present invention.
- the subsystem 10 shown in FIG. 13 is the same as that shown in any of FIGS. 2 to 4, and the components of the ultraviolet oxidizer, non-regenerative ion exchanger, membrane separator and membrane deaerator are omitted from the figure. It is.
- the water outlet of the subsystem and the water inlet of each substrate processing apparatus are connected via a main pipe made of PVC, PFA or the like mainly used in a semiconductor manufacturing line.
- a processing chamber is installed in the substrate processing apparatus 1 (not shown), and cleaning water is supplied.
- a mechanism for holding substrates is installed in the processing chamber, and the mechanism is a single wafer type in which carbonated water is sprayed on a single substrate, or a plurality of substrates are immersed in a tank in which carbonated water is stored. Any of the batch types to be processed.
- the hydrogen peroxide removal device 2 and the carbon dioxide supply device 4 are installed in this order in the water supply direction between the water outlet 10a of the subsystem and the water inlet 1a of the substrate processing apparatus.
- the hydrogen peroxide removing device 2 and the carbon dioxide supply device 4 have an advantage that they can be installed only in the substrate processing apparatus 1 that requires carbonated water having a reduced hydrogen peroxide concentration.
- the subsystem 10 since the subsystem 10 has the same configuration as the conventional one, there is an advantage that it is not necessary to change existing facilities.
- the hydrogen peroxide removal device 2 uses a platinum group metal catalyst.
- a catalyst column packed with a palladium catalyst or a palladium catalyst supported on a monolithic organic porous anion exchanger Catalyst columns.
- the catalyst column in which the palladium catalyst is supported on the monolithic organic porous anion exchanger is much smaller than the catalyst column in which the palladium catalyst is supported on the granular ion exchanger.
- This is suitable for an embodiment in which the hydrogen removing apparatus 2 is attached to the substrate processing apparatus 1. More specific examples of the platinum group metal catalyst will be described later.
- a filter is disposed after the catalyst column packed with the platinum group metal catalyst. It is particularly preferable to use a microfiltration membrane as the filter. Furthermore, for the purpose of preventing the outflow of ionic components in addition to the fine particles, it is also preferable to arrange an ion adsorption membrane or a combination of an ion adsorption membrane and a microfiltration membrane as a filter in the subsequent stage of the catalyst column. It is also preferable to arrange a monolith cation exchanger and / or a combination of a monolith anion exchanger and a microfiltration membrane in the subsequent stage of the catalyst column.
- This third embodiment has the same effects as the first embodiment. That is, in the substrate processing apparatus 1, carbon dioxide is reduced so that the hydrogen peroxide concentration is reduced to 2 ⁇ g / L or less and the specific resistance is 0.03 M ⁇ ⁇ cm to 5.0 M ⁇ ⁇ cm. Carbonated water to which is added is supplied. If this carbonated water is used for cleaning the substrate, the dissolution of copper exposed on the substrate surface can be further suppressed as compared with the conventional carbonated water whose hydrogen peroxide concentration is not suppressed to 2 ⁇ g / L or less. This is based on the evaluation result shown in the Example mentioned later.
- the processing chamber of the substrate processing apparatus 1 it is desirable to fill the processing chamber of the substrate processing apparatus 1 with an inert gas so that the oxygen gas concentration in the processing chamber is 2% or less.
- Nitrogen gas can be suitably used as the inert gas from the viewpoint of economy. This is based on the test results described in the examples.
- the processing chamber of the substrate processing apparatus 1 it is preferable to shield the processing chamber of the substrate processing apparatus 1 from light during the substrate cleaning process. This is based on the test results described in the examples.
- FIG. 15 is a schematic view showing an aspect of the substrate cleaning method according to the third embodiment of the present invention.
- the subsystem shown in FIG. 15 is the same as that shown in any of FIGS. 2 to 4, and the components of the ultraviolet oxidizer, non-regenerative ion exchanger, membrane separator and membrane deaerator are omitted from the figure. It is.
- the water outlet of the subsystem and the water inlet of each substrate processing apparatus are connected via a main pipe made of PVC, PFA or the like mainly used in a semiconductor manufacturing line.
- a processing chamber is installed in the substrate processing apparatus 1 (not shown), and cleaning water is supplied.
- a mechanism for holding substrates is installed in the processing chamber, and the mechanism is a single wafer type in which carbonated water is sprayed on a single substrate, or a plurality of substrates are immersed in a tank in which carbonated water is stored. Any of the batch types to be processed.
- the hydrogen supply device 5, the hydrogen peroxide removal device 2, and the carbon dioxide supply device 4 are installed in this order in the water supply direction between the water outlet 10a of the subsystem and the water inlet 1a of the substrate processing apparatus.
- the hydrogen supply device 5, the hydrogen peroxide removal device 2, and the carbon dioxide supply device 4 can be installed only in the substrate processing apparatus 1 that requires carbonated water with reduced hydrogen peroxide concentration and dissolved oxygen concentration.
- the subsystem 10 since the subsystem 10 has the same configuration as the conventional one, there is an advantage that it is not necessary to change existing facilities.
- the hydrogen peroxide removal device 2 uses a platinum group metal catalyst.
- a catalyst column packed with a palladium catalyst or a palladium catalyst supported on a monolithic organic porous anion exchanger Catalyst columns.
- the catalyst column in which the palladium catalyst is supported on the monolithic organic porous anion exchanger is much smaller than the catalyst column in which the palladium catalyst is supported on the granular ion exchanger.
- This is suitable for an embodiment in which the hydrogen removing apparatus 2 is attached to the substrate processing apparatus 1. More specific examples of the platinum group metal catalyst will be described later.
- a filter is disposed after the catalyst column packed with the platinum group metal catalyst. It is particularly preferable to use a microfiltration membrane as the filter. Furthermore, for the purpose of preventing the outflow of ionic components in addition to the fine particles, it is also preferable to arrange an ion adsorption membrane or a combination of an ion adsorption membrane and a microfiltration membrane as a filter in the subsequent stage of the catalyst column. It is also preferable to arrange a monolith cation exchanger and / or a combination of a monolith anion exchanger and a microfiltration membrane in the subsequent stage of the catalyst column.
- hydrogen peroxide is reduced so that the hydrogen peroxide concentration is 2 ⁇ g / L or less, and the specific resistance is 0.03 M ⁇ ⁇ cm to 5.0 M ⁇ ⁇ cm.
- Carbonated water to which carbon dioxide has been added is supplied. If this carbonated water is used for cleaning the substrate, the dissolution of copper exposed on the substrate surface can be further suppressed as compared with the conventional carbonated water whose hydrogen peroxide concentration is not suppressed to 2 ⁇ g / L or less.
- this fourth embodiment can remove dissolved oxygen as in the second embodiment described above, but the hydrogen peroxide removing device 2 is closer to the substrate processing apparatus 1 than the second embodiment. Is installed. Therefore, compared with the second embodiment, even if oxygen is dissolved in the pipe from the subsystem to the substrate processing apparatus 1, the joint portion, etc. into the pipe and the dissolved oxygen concentration is increased, the dissolved oxygen immediately before the substrate processing apparatus 1. Therefore, it is possible to obtain carbonated water in which dissolved oxygen is further reduced.
- the hydrogen peroxide removing apparatus 2 serving as an apparatus for removing dissolved oxygen may be installed inside the substrate processing apparatus 1.
- the hydrogen supply device 5 may also be installed inside the substrate processing apparatus 1.
- the installation space becomes a problem, and therefore it is particularly preferable to use a catalyst column in which a palladium catalyst is supported on a monolithic organic porous anion exchanger. .
- FIG. 17 a hydrogen water supply system 11 that supplies hydrogen water to the subsequent stage of the subsystem 10 is connected, and between the water outlet 11 a of the hydrogen water supply system and the water inlet 1 a of the substrate processing apparatus, The hydrogen peroxide removing device 2 and the carbon dioxide supply device 4 are installed in this order in the water supply direction.
- the hydrogen water supply system 11 includes a hydrogen supply device, a water pump, and a hydrogen water tank (not shown), and hydrogen water that has not been used in the substrate processing apparatus 1 is returned.
- the hydrogen peroxide removing device 2 and the carbon dioxide supply device 4 can be installed only in the substrate processing apparatus 1 that requires carbonated water with reduced hydrogen peroxide concentration and dissolved oxygen concentration. is there.
- the processing chamber of the substrate processing apparatus 1 it is desirable to fill the processing chamber of the substrate processing apparatus 1 with an inert gas so that the oxygen gas concentration in the processing chamber is 2% or less.
- Nitrogen gas can be suitably used as the inert gas from the viewpoint of economy. This is based on the test results described in the examples.
- the processing chamber of the substrate processing apparatus 1 it is preferable to shield the processing chamber of the substrate processing apparatus 1 from light during the substrate cleaning process. This is based on the test results described in the examples.
- FIG. 18 is a schematic diagram showing an aspect of the substrate cleaning method according to the fifth embodiment of the present invention.
- the subsystem shown in FIG. 18 is the same as that shown in any of FIGS. 2 to 4, and the components of the ultraviolet oxidizer, non-regenerative ion exchanger, membrane separator and membrane deaerator are omitted from the figure. It is.
- the water outlet of the subsystem and the water inlet of each substrate processing apparatus are connected via a main pipe made of PVC, PFA or the like mainly used in a semiconductor manufacturing line.
- a processing chamber is installed in the substrate processing apparatus 1 and is supplied with cleaning water. There may be one or more substrate processing apparatuses 1, and one or more processing chambers of each substrate processing apparatus 1 may be provided.
- a mechanism for holding substrates is installed in the processing chamber, and the mechanism is a single wafer type in which carbonated water is sprayed on a single substrate, or a plurality of substrates are immersed in a tank in which carbonated water is stored. Any of the batch types to be processed.
- the hydrogen supply device 5, the carbon dioxide supply device 4, and the hydrogen peroxide removal device 2 are installed in this order in the water supply direction between the water outlet 10a of the subsystem and the water inlet of the processing chamber. Yes.
- the order of the carbon dioxide supply device 4, the hydrogen supply device 5, and the hydrogen peroxide removal device 2 may be used.
- hydrogen and carbon dioxide may not be supplied by separate supply apparatuses, but may be supplied to raw water after hydrogen and carbon dioxide are merged in a pipe.
- the hydrogen supply device 5, the carbon dioxide supply device 4, and the hydrogen peroxide removal device 2 can be installed only in the substrate processing apparatus 1 that requires carbonated water with reduced hydrogen peroxide concentration and dissolved oxygen concentration.
- the hydrogen peroxide removing device 2 uses a platinum group metal catalyst, for example, a catalyst column packed with a palladium catalyst, or a palladium catalyst supported on a monolithic organic porous anion exchanger. Catalyst columns.
- the catalyst column in which the palladium catalyst is supported on the monolithic organic porous anion exchanger is much smaller than the catalyst column in which the palladium catalyst is supported on the granular ion exchanger.
- the monolithic organic porous anion exchanger supported on the palladium catalyst is preferably a carbonate type. More specific examples of the platinum group metal catalyst will be described later.
- the hydrogen peroxide removing apparatus 2 it is particularly preferable to install the hydrogen peroxide removing apparatus 2 inside the substrate processing apparatus 1 as shown in FIG. Further, the carbon dioxide supply device 4 or the hydrogen supply device 5, or the carbon dioxide supply device 4 and the hydrogen supply device 5 may be installed inside the substrate processing apparatus 1.
- the substrate processing apparatus 1 hydrogen peroxide is reduced so that the hydrogen peroxide concentration is 2 ⁇ g / L or less, and the specific resistance is 0.03 M ⁇ ⁇ cm to 5.0 M ⁇ ⁇ cm.
- Carbonated water to which carbon dioxide has been added is supplied. If this carbonated water is used for cleaning the substrate, the dissolution of copper exposed on the substrate surface can be further suppressed as compared with the conventional carbonated water whose hydrogen peroxide concentration is not suppressed to 2 ⁇ g / L or less.
- this fifth embodiment can remove dissolved oxygen in the same way as the second embodiment and the fourth embodiment described above, but hydrogen peroxide is compared with the second embodiment and the fourth embodiment.
- a removal apparatus 2 is installed near the processing chamber of the substrate processing apparatus. Therefore, compared with the second embodiment and the fourth embodiment, even if oxygen is dissolved into the pipe from the pipe, the joint portion, etc. from the subsystem to the processing chamber of the substrate processing apparatus 1 and the dissolved oxygen concentration is increased, the substrate Since it is possible to remove dissolved oxygen immediately before the treatment chamber of the treatment apparatus 1, it is possible to obtain carbonated water with reduced dissolved oxygen.
- FIG. 19 another aspect of this embodiment is shown in FIG.
- a carbonated water supply system 12 that supplies carbonated water is connected to the subsequent stage of the subsystem 10, and hydrogen is supplied between the water outlet 12a of the carbonated water supply system and the water inlet of the processing chamber.
- the apparatus 5 and the hydrogen peroxide removing apparatus 2 are installed in this order in the water supply direction.
- the carbonated water supply system 12 includes a carbon dioxide supply device, a water supply pump, and a carbonated water tank (not shown), and carbonated water that has not been used in the substrate processing apparatus 1 is returned.
- the hydrogen supply device 5 and the hydrogen peroxide removal device 2 have the advantage that they can be installed only in the substrate processing apparatus 1 that requires carbonated water with reduced hydrogen peroxide concentration and dissolved oxygen concentration. .
- FIG. 20 Another aspect of this embodiment is shown in FIG.
- a hydrogen water supply system 11 for supplying hydrogen water to the subsystem is connected, and the carbon dioxide supply device 4 is provided between the water outlet 11a of the hydrogen water supply system and the water inlet of the treatment chamber.
- the hydrogen peroxide removal apparatus 2 is installed in this order in the water supply direction.
- the hydrogen water supply system 11 includes a hydrogen supply device, a water pump, and a hydrogen water tank (not shown), and hydrogen water that has not been used in the substrate processing apparatus 1 is returned.
- the hydrogen peroxide removing device 2 and the carbon dioxide supply device 2 have an advantage that they can be installed only in a substrate processing apparatus that requires carbonated water with reduced hydrogen peroxide concentration and dissolved oxygen concentration. .
- the processing chamber of the substrate processing apparatus 1 it is desirable to fill the processing chamber of the substrate processing apparatus 1 with an inert gas so that the oxygen gas concentration in the processing chamber is 2% or less.
- Nitrogen gas can be suitably used as the inert gas from the viewpoint of economy. This is based on the test results described in the examples.
- the processing chamber of the substrate processing apparatus 1 it is preferable to shield the processing chamber of the substrate processing apparatus 1 from light during the substrate cleaning process. This is based on the test results described in the examples.
- Platinum group metal catalyst A specific example of the catalyst capable of removing hydrogen peroxide and removing oxygen used in the hydrogen peroxide removing apparatus 2 described above will be described in detail.
- the catalyst includes a granular ion exchange resin carrying a platinum group metal, a metal ion type granular cation exchange resin, a non-particulate organic porous material carrying a platinum group metal or a platinum group metal.
- a granular ion exchange resin carrying a platinum group metal carrying a platinum group metal
- a metal ion type granular cation exchange resin carrying a platinum group metal or a platinum group metal.
- Non-particulate organic porous ion exchangers Non-particulate organic porous ion exchangers.
- Platinum group metal-supported non-particulate organic porous body platinum group metal-supported non-particulate organic porous ion exchanger
- As the platinum group metal-supported non-particulate organic porous material fine particles of platinum group metal having an average particle diameter of 1 to 1000 nm are supported on the non-particulate organic porous material.
- the continuous skeleton has a thickness of 1 to 100 ⁇ m, the average diameter of the continuous pores is 1 to 1000 ⁇ m, the total pore volume is 0.5 to 50 mL / g, and the supported amount of platinum group metal is Examples thereof include a platinum group metal-supported non-particulate organic porous material having a dry state of 0.004 to 20% by weight.
- platinum group metal-supported non-particulate organic porous ion exchanger platinum group metal fine particles having an average particle diameter of 1 to 1000 nm are supported on the non-particulate organic porous ion exchanger, and the non-particulate organic porous ion exchanger is supported.
- the ion exchanger is composed of a continuous skeleton phase and a continuous pore phase.
- the thickness of the continuous skeleton is 1 to 100 ⁇ m
- the average diameter of the continuous pores is 1 to 1000 ⁇ m
- the total pore volume is 0.5 to 50 mL / g.
- the ion exchange capacity per weight in the dry state is 1 to 6 mg equivalent / g
- the ion exchange groups are uniformly distributed in the organic porous ion exchanger
- the supported amount of the platinum group metal is in the dry state.
- a platinum group metal-supported non-particulate organic porous ion exchanger in an amount of 0.004 to 20% by weight.
- the average diameter of the opening of a non-particulate organic porous body or a non-particulate organic porous ion exchanger is measured by a mercury intrusion method, and indicates the maximum value of a pore distribution curve obtained by the mercury intrusion method.
- the structure of the non-particulate organic porous body or non-particulate organic porous ion exchanger and the thickness of the continuous skeleton are determined by SEM observation.
- the particle diameter of the platinum group metal nanoparticles supported on the non-particulate organic porous body or the non-particulate organic porous ion exchanger is determined by TEM observation.
- the platinum group metal-supported non-particulate organic porous body or the platinum group metal-supported non-particulate organic porous ion exchanger has an average particle diameter of 1 to 1000 nm compared to the non-particulate organic porous body or non-particulate organic porous ion exchanger. Since the platinum group metal is supported, it exhibits high hydrogen peroxide decomposition catalytic activity and can pass raw water at a space velocity (SV) of 200 to 20000 h ⁇ 1, preferably 2000 to 20000 h ⁇ 1. .
- SV space velocity
- the carrier on which the platinum group metal is supported is a non-particulate organic porous body.
- This non-particulate organic porous exchanger is a monolithic organic porous exchange. Is the body.
- the carrier on which the platinum group metal is supported is a non-particulate organic porous ion exchanger.
- the monolithic organic porous body is a porous body having a skeleton formed of an organic polymer and a large number of communication holes serving as a flow path for the reaction solution between the skeletons.
- the monolithic organic porous ion exchanger is a porous body introduced so that ion exchange groups are uniformly distributed in the skeleton of the monolithic organic porous body.
- “monolithic organic porous material” is also simply referred to as “monolith”
- “monolithic organic porous ion exchanger” is also simply referred to as “monolith ion exchanger”, and is also an intermediate in the production of monoliths.
- the “monolithic organic porous intermediate” that is the body (precursor) is also simply referred to as “monolith intermediate”.
- Examples of the structure of such a monolith or monolith ion exchanger are disclosed in Japanese Patent Application Laid-Open No. 2002-306976 and Japanese Patent Application Laid-Open No. 2009-62512, and Japanese Patent Application Laid-Open No. 2009-67982.
- the thickness of the continuous skeleton in the dry state of the monolith or monolith ion exchanger according to the platinum group metal supported catalyst of the present invention is 1 to 100 ⁇ m.
- the thickness of the continuous skeleton of the monolith ion exchanger is less than 1 ⁇ m, the ion exchange capacity per volume decreases, and the mechanical strength decreases. Since the exchanger is greatly deformed, it is not preferable. Furthermore, the contact efficiency between the reaction solution and the monolith ion exchanger is lowered, and the catalytic activity is lowered, which is not preferable.
- the thickness of the continuous skeleton of the monolith ion exchanger exceeds 100 ⁇ m, the skeleton becomes too thick and pressure loss during liquid passage increases, which is not preferable.
- the average diameter of the continuous pores in the dry state of the monolith or monolith ion exchanger according to the platinum group metal supported catalyst of the present invention is 1 to 1000 ⁇ m. If the average diameter of the continuous pores of the monolith ion exchanger is less than 1 ⁇ m, it is not preferable because the pressure loss during liquid passage increases. On the other hand, if the average diameter of the continuous pores of the monolith ion exchanger exceeds 1000 ⁇ m, the contact between the reaction solution and the monolith ion exchanger becomes insufficient and the catalytic activity is lowered, which is not preferable.
- monoliths serving as carriers for the above monolith that is, platinum group metal particles (hereinafter also referred to as monolith (1)) and monolith ion exchangers, that is, monolith ion exchangers serving as the carrier for platinum group metal particles
- monolith ion exchanger (1) examples include monoliths and monolith ion exchangers having a co-continuous structure disclosed in JP-A-2009-67982.
- the monolith (1) is a monolith before an ion exchange group is introduced, and has an average thickness composed of an aromatic vinyl polymer containing 0.1 to 5.0 mol% of a crosslinked structural unit among all the structural units.
- the monolith ion exchanger (1) is a three-dimensional one having an average thickness of 1 to 60 ⁇ m in the dry state made of an aromatic vinyl polymer containing 0.1 to 5.0 mol% of a crosslinked structural unit among all the structural units.
- a co-continuous structure consisting of a continuous skeleton and three-dimensionally continuous pores having an average diameter of 10 to 200 ⁇ m in the dry state between the skeletons, and the total pore volume in the dry state is 0 5 to 10 mL / g, having an ion exchange group, an ion exchange capacity per weight in a dry state of 1 to 6 mg equivalent / g, and the ion exchange group in the organic porous ion exchanger It is a monolithic ion exchanger that is uniformly distributed.
- the monolith (1) or monolith ion exchanger (1) has a three-dimensional continuous skeleton having an average thickness of 1 to 60 ⁇ m, preferably 3 to 58 ⁇ m in a dry state, and an average diameter between the skeletons in a dry state.
- a co-continuous structure consisting of three-dimensionally continuous pores of 10 to 200 ⁇ m, preferably 15 to 180 ⁇ m, particularly preferably 20 to 150 ⁇ m.
- the co-continuous structure is a structure in which a continuous skeleton phase and a continuous vacancy phase are intertwined, and both are three-dimensionally continuous.
- the continuous pores have higher continuity of the pores than the conventional open-cell type monolith and the particle aggregation type monolith, and the size thereof is not biased.
- the mechanical strength is high.
- the average diameter of the opening of the monolith (1) in the dry state, the average diameter of the opening of the monolith ion exchanger (1) and the opening of the monolith intermediate (1) in the dry state obtained by the I treatment in the production of the monolith described below The average diameter is measured by the mercury intrusion method and refers to the maximum value of the pore distribution curve obtained by the mercury intrusion method.
- the average thickness of the skeleton of the monolith (1) or the monolith ion exchanger (1) in the dry state can be obtained by SEM observation of the dry monolith (1) or the monolith ion exchanger (1).
- the SEM observation of the dried monolith (1) or monolith ion exchanger (1) is performed at least three times, the thickness of the skeleton in the obtained image is measured, and the average value thereof is calculated as the average thickness.
- the skeleton has a rod-like shape and a circular cross-sectional shape, but may have a cross-section with a different diameter such as an elliptical cross-sectional shape.
- the thickness in this case is the average of the minor axis and the major axis.
- the total pore volume per weight in the dry state of the monolith (1) or the monolith ion exchanger (1) is 0.5 to 10 mL / g. If the total pore volume is less than 0.5 mL / g, the pressure loss at the time of liquid passing increases, which is not preferable. Further, the permeation amount per unit cross-sectional area decreases, and the throughput decreases. Therefore, it is not preferable. On the other hand, if the total pore volume exceeds 10 mL / g, the mechanical strength is lowered, and the monolith or the monolith ion exchanger is greatly deformed particularly when the liquid is passed at a high flow rate.
- the catalyst efficiency is also lowered, which is not preferable. If the three-dimensionally continuous pore size and total pore volume are within the above ranges, the contact with the reaction solution is extremely uniform, the contact area is large, and the solution can be passed under a low pressure loss. .
- the material constituting the skeleton comprises 0.1 to 5 mol%, preferably 0.5 to 3.0 mol% of a crosslinked structural unit in all the structural units. It is an aromatic vinyl polymer containing and is hydrophobic. If the cross-linking structural unit is less than 0.1 mol%, the mechanical strength is insufficient, which is not preferable. On the other hand, if it exceeds 5 mol%, the structure of the porous body tends to deviate from the bicontinuous structure.
- aromatic vinyl polymer For example, a polystyrene, poly ((alpha) -methylstyrene), polyvinyl toluene, polyvinyl benzyl chloride, polyvinyl biphenyl, polyvinyl naphthalene etc. are mentioned.
- the polymer may be a polymer obtained by copolymerizing a single vinyl monomer and a crosslinking agent, a polymer obtained by polymerizing a plurality of vinyl monomers and a crosslinking agent, or a blend of two or more types of polymers. It may be what was done.
- the styrene-divinylbenzene copolymer is easy because of its co-continuous structure formation, ease of ion exchange group introduction and high mechanical strength, and high stability against acids or alkalis.
- a polymer or a vinylbenzyl chloride-divinylbenzene copolymer is preferred.
- the introduced ion exchange groups are uniformly distributed not only on the surface of the monolith but also within the skeleton of the monolith.
- “ion exchange groups are uniformly distributed” means that the distribution of ion exchange groups is uniformly distributed on the surface and inside the skeleton in the order of at least ⁇ m. The distribution status of the ion exchange groups can be easily confirmed by using EPMA.
- the ion exchange groups are uniformly distributed not only on the surface of the monolith but also within the skeleton of the monolith, the physical and chemical properties of the surface and the interior can be made uniform, so that they are resistant to swelling and shrinkage. Improves.
- the ion exchange group introduced into the monolith ion exchanger (1) is a cation exchange group or an anion exchange group.
- the cation exchange group include a carboxylic acid group, an iminodiacetic acid group, a sulfonic acid group, a phosphoric acid group, and a phosphoric ester group.
- anion exchange groups include trimethylammonium group, triethylammonium group, tributylammonium group, dimethylhydroxyethylammonium group, dimethylhydroxypropylammonium group, methyldihydroxyethylammonium group, quaternary ammonium group, tertiary sulfonium group, phosphonium group. Etc.
- the monolith ion exchanger (1) has an ion exchange capacity of 1 to 6 mg equivalent / g of ion exchange capacity per weight in a dry state. Since the monolith ion exchanger (1) has high continuity and uniformity of three-dimensionally continuous pores, the pressure loss does not increase so much even if the total pore volume is reduced. Therefore, it is possible to dramatically increase the ion exchange capacity per volume while keeping the pressure loss low. When the ion exchange capacity per weight is in the above range, the environment around the catalyst active point such as the pH inside the catalyst can be changed, and thereby the catalyst activity is increased.
- the monolith ion exchanger (1) is a monolith anion exchanger
- an anion exchange group is introduced into the monolith anion exchanger (1), and the anion exchange capacity per weight in the dry state is 1 to 6 mg. Equivalent / g.
- a cation exchange group is introduced into the monolith cation exchanger (1), and the cation exchange capacity per weight in a dry state is 1 ⁇ 6 mg equivalent / g.
- the monolith (1) can be obtained by carrying out the method for producing a monolithic organic porous material disclosed in JP-A-2009-66792.
- the manufacturing method is A water-in-oil emulsion is prepared by stirring a mixture of oil-soluble monomer, surfactant and water that does not contain ion exchange groups, and then the water-in-oil emulsion is polymerized to a total pore volume of 16 mL / g.
- monolith intermediate (1) a monolith-like organic porous intermediate having a continuous macropore structure exceeding 30 mL / g
- Aromatic vinyl monomer, 0.3 to 5 mol% of cross-linking agent, aromatic vinyl monomer or cross-linking agent dissolves in all oil-soluble monomer having at least 2 vinyl groups in one molecule, but aromatic vinyl monomer II process for preparing a mixture comprising an organic solvent and a polymerization initiator that does not dissolve the polymer produced by polymerization, and the monolith intermediate (1 obtained by standing the mixture obtained by the II process and by the I process)
- a platinum group metal is supported on the platinum group metal-supported non-particulate organic porous material or the platinum group metal-supported non-particulate organic porous ion exchanger.
- the platinum group metal is ruthenium, rhodium, palladium, osmium, iridium, or platinum. These platinum group metals may be used alone or in combination of two or more metals, and more than one metal may be used as an alloy. Among these, platinum, palladium, and platinum / palladium alloys have high catalytic activity and are preferably used.
- the average particle size of the platinum group metal-supported non-particulate organic porous material or platinum group metal-supported non-particulate organic porous ion exchanger is 1 to 1000 nm, preferably 1 to 200 nm, More preferably, it is 1 to 20 nm. If the average particle diameter is less than 1 nm, the possibility that the platinum group metal particles are detached from the carrier increases, which is not preferable. On the other hand, when the average particle diameter exceeds 200 nm, the surface area per unit mass of the metal is reduced, and the catalytic effect cannot be obtained efficiently. In addition, the average particle diameter of a platinum group metal particle is calculated
- TEM transmission electron microscope
- Platinum group metal-supported non-particulate organic porous material or platinum group metal-supported non-particulate organic porous ion exchanger supported amount of platinum group metal particles ((platinum group metal particles / platinum group metal-supported catalyst in a dry state)) ⁇ 100 ) Is 0.004 to 20% by weight, preferably 0.005 to 15% by weight. If the supported amount of platinum group metal particles is less than 0.004% by weight, the catalytic activity becomes insufficient, such being undesirable. On the other hand, when the amount of platinum group metal particles is more than 20% by weight, metal elution into water is observed, which is not preferable.
- a platinum group metal-supported catalyst can be obtained by supporting fine particles of platinum group metal on a monolith or a monolith ion exchanger by a known method.
- Examples of the method for supporting the platinum group metal on the non-particulate organic porous body or the non-particulate organic porous ion exchanger include the method disclosed in JP 2010-240641 A.
- a dried monolith ion exchanger is immersed in a methanol solution of a platinum group metal compound such as palladium acetate, and palladium ions are adsorbed on the monolith ion exchanger by ion exchange, and then contacted with a reducing agent to form palladium metal fine particles.
- a platinum group metal compound such as palladium acetate
- palladium ions are adsorbed on the monolith ion exchanger by ion exchange, and then contacted with a reducing agent to form palladium metal fine particles.
- the granular ion exchange resin carrying a platinum group metal is a granular ion exchange resin carrying a platinum group metal.
- the particulate ion exchange resin that serves as the platinum group metal carrier is not particularly limited, and examples thereof include strongly basic anion exchange resins. Then, the granular ion exchange resin is loaded with a platinum group metal by a known method to obtain a granular ion exchange resin loaded with the platinum group metal.
- the metal ion-type granular cation exchange resin carrying a metal is one in which a metal such as iron ion, copper ion, nickel ion, chromium ion or cobalt ion is carried on a granular cation exchange resin.
- the granular cation exchange resin to be a carrier is not particularly limited, and examples thereof include strongly acidic cation exchange resins.
- metal, such as an iron ion, copper ion, nickel ion, chromium ion, and cobalt ion, is carry
- the styrene / divinylbenzene / SMO / 2,2′-azobis (isobutyronitrile) mixture was added to 180 g of pure water, and a vacuum stirring defoaming mixer (manufactured by EM Co.) as a planetary stirring device.
- EM Co. vacuum stirring defoaming mixer
- This emulsion was quickly transferred to a reaction vessel and allowed to polymerize at 60 ° C. for 24 hours in a static state after sealing.
- the content was taken out, extracted with methanol, and then dried under reduced pressure to produce a monolith intermediate having a continuous macropore structure.
- the internal structure of the monolith intermediate (dry body) thus obtained was observed by SEM. From the SEM image, although the wall section that divides two adjacent macropores is very thin and rod-shaped, it has an open cell structure, and the average of the openings (mesopores) where the macropores and macropores overlap measured by the mercury intrusion method The diameter was 40 ⁇ m and the total pore volume was 18.2 mL / g.
- the internal structure of a monolith (dry body) containing 1.2 mol% of a crosslinking component composed of the styrene / divinylbenzene copolymer thus obtained was observed by SEM. From the SEM observation, the monolith has a co-continuous structure in which the skeleton and the vacancies are three-dimensionally continuous, and both phases are intertwined. Moreover, the average thickness of the skeleton measured from the SEM image was 20 ⁇ m. Further, the average diameter of the three-dimensionally continuous pores of the monolith measured by mercury porosimetry was 70 ⁇ m, and the total pore volume was 4.4 mL / g. The average diameter of the pores was determined from the maximum value of the pore distribution curve obtained by the mercury intrusion method.
- the monolith produced by the above method is put into a column reactor, and a solution consisting of 1600 g of chlorosulfonic acid, 400 g of tin tetrachloride and 2500 mL of dimethoxymethane is circulated and passed through, and reacted at 30 ° C. for 5 hours. Was introduced.
- 1600 mL of THF and 1400 mL of a 30% trimethylamine aqueous solution were added and reacted at 60 ° C. for 6 hours.
- the product was washed with methanol and then with pure water to obtain a monolith anion exchanger.
- the anion exchange capacity of the obtained monolith anion exchanger was 4.2 mg equivalent / g in a dry state, and it was confirmed that quaternary ammonium groups were introduced quantitatively. Further, the thickness of the skeleton in the dry state measured from the SEM image is 20 ⁇ m, and the average diameter in the dry state of the three-dimensional continuous pores of the monolith anion exchanger determined from the measurement by the mercury intrusion method. was 70 ⁇ m, and the total pore volume in the dry state was 4.4 mL / g.
- the monolith anion exchanger was treated with an aqueous hydrochloric acid solution to form a chloride form, and then the distribution state of chloride ions was observed by EPMA. .
- the chloride ions were uniformly distributed not only on the skeleton surface of the monolith anion exchanger but also inside the skeleton, and the quaternary ammonium groups were uniformly introduced into the monolith anion exchanger. It was.
- the monolith anion exchanger was ion-exchanged into Cl form, cut into a cylindrical shape in a dry state, and dried under reduced pressure. The weight of the monolith anion exchanger after drying was 2.1 g. This dried monolith anion exchanger was immersed in dilute hydrochloric acid in which 160 mg of palladium chloride was dissolved, and ion-exchanged into the palladium chloride acid form. After completion of the immersion, the monolith anion exchanger was washed several times with pure water, and immersed in an aqueous hydrazine solution for 24 hours for reduction treatment.
- the chloropalladium acid form monolith anion exchanger was brown, whereas the monolith anion exchanger after the reduction treatment was colored black, suggesting the formation of palladium fine particles.
- the sample after reduction was washed several times with pure water and then dried under reduced pressure.
- the obtained palladium fine particle-supported catalyst in a dry state was packed in a column having an inner diameter of 57 mm so that the layer height was 40 mm, and an aqueous sodium hydroxide solution was passed through to make the monolith anion exchanger as a carrier into OH form. Further, when the ionic form was changed to the carbonate form, an aqueous ammonium hydrogen carbonate solution was passed.
- the amount of palladium supported was determined by ICP emission spectrometry, and the amount of palladium supported was 3.9% by weight.
- the distribution state of palladium was observed by EPMA. It was confirmed that palladium was distributed not only on the surface of the skeleton of the monolith anion exchanger but also on the inside of the skeleton.
- observation with a transmission electron microscope (TEM) was performed. The average particle diameter of the palladium fine particles was 8 nm.
- a single wafer cleaning device manufactured by Zenkyo Kasei Kogyo Co., Ltd. was used as the substrate processing apparatus.
- the above-mentioned 24 mm square sample is set at the center of the substrate holder of this apparatus, and carbonated water is washed over the sample for a predetermined time while rotating at 500 rpm.
- Carbonated water to be evaluated was prepared by adjusting the water quality shown in the following various test examples using the following ultrapure water as raw water.
- a catalyst column in which a palladium catalyst was supported on a monolithic organic porous anion exchanger was used. The method for synthesizing the catalyst is as described above.
- the sheet resistance was measured using a ⁇ -5 + type four deep needle method measuring instrument manufactured by NP.
- the increase in sheet resistance due to the treatment means a decrease in the thickness of the copper thin film or formation of a nonconductor on the copper thin film, and in either case, it results from corrosion of copper.
- Hak Ultra 510 type measuring instrument for dissolved oxygen concentration meter DHDI-I type measuring device made by Toa DKK Corporation for dissolved hydrogen concentration meter, MH-7 type measuring instrument made by Organo for specific resistance measurement was used. The measurement of hydrogen peroxide concentration was performed using the phenol phthaline method.
- Example 1 This test was performed using the test line shown in FIG. After removing hydrogen peroxide from the secondary pure water (ultra pure water) of the ultrapure water production equipment through the catalyst column and passing through the filter (microfiltration membrane), dissolve the carbon dioxide using the carbon dioxide dissolution membrane. The specific resistance was 0.1 M ⁇ ⁇ cm. The carbonated water produced in this way was introduced into the processing chamber in the single wafer cleaning apparatus, and the sample was cleaned for 2 hours. Table 2 shows values obtained by converting the increment of the measured sheet resistance value after cleaning with respect to the measured sheet resistance value before cleaning, per hour. The concentration of hydrogen peroxide contained in the treated water at this time was 2 ⁇ g / L or less.
- the dissolved oxygen concentration at the outlet of the ultrapure water production apparatus is 2 ⁇ g / L or less, but the dissolved oxygen concentration is 30 ⁇ g / L immediately before the processing chamber due to the penetration of air in the PFA piping and joints. It is guessed that it rose to
- FIGS. 22-1a and 22-2a show images obtained by SPM (scanning probe microscope) observation, respectively, in FIGS. 22-1b and 22-2b.
- SPM scanning probe microscope
- Example 2 This test was performed using the test line shown in FIG. After dissolving oxygen gas of a predetermined concentration in secondary pure water (ultra pure water) of ultrapure water production equipment using an oxygen-dissolving membrane, the oxygen-dissolved water is removed through a catalyst column to remove hydrogen peroxide. The specific resistance was adjusted to 0.1 M ⁇ ⁇ cm by passing through a filter (microfiltration membrane) and dissolving carbon dioxide using a carbon dioxide-dissolving membrane. The carbonated water produced in this way was introduced into the processing chamber in the single wafer cleaning apparatus, and the sample was cleaned for 2 hours. Table 3 shows values obtained by converting the increment of the measured sheet resistance value after cleaning with respect to the measured sheet resistance value before cleaning per hour. The concentration of hydrogen peroxide contained in the treated water at this time was 2 ⁇ g / L or less. The dissolved oxygen concentration was measured by extracting a part of the treated water immediately before the treatment chamber in the single wafer cleaning apparatus.
- Example 2-1 is compared with Comparative Example 2-1
- Example 2-2 is compared with Comparative Example 2-2
- such dissolved oxygen is present to a certain extent (130 ⁇ g / L, 800 ⁇ g / L).
- cleaning with carbonated water whose hydrogen peroxide concentration has been reduced to 2 ⁇ g / L or less reduces the increase in sheet resistance, that is, suppresses copper corrosion, compared to the case where hydrogen peroxide is not removed. Is clear.
- the dissolved oxygen concentration immediately before the treatment chamber in the single wafer cleaning apparatus was 130 ⁇ g / L or less, and the hydrogen peroxide concentration was reduced to 2 ⁇ g / L or less. It is clear that carbonated water reduces sheet resistance increments, ie, suppresses copper corrosion.
- Example 3 In the test of Example 1, the test was performed with the process chamber shielded from light. The results are shown in Table 4.
- Example 4 In the test of Example 1, a cleaning test was performed under the condition that nitrogen gas was introduced into the processing chamber and the oxygen gas concentration was 2% or less. The results are shown in Table 5.
- Example 5 This test was performed using the test line shown in FIG. Hydrogen gas is dissolved in secondary pure water (ultra pure water) of the ultrapure water production apparatus using a hydrogen-dissolving membrane, and carbon dioxide is dissolved using a carbon dioxide-dissolving membrane, so that the specific resistance is 0.1 M ⁇ ⁇ cm. It was. The carbonated water thus produced was introduced into a single wafer cleaning apparatus. Inside the single wafer cleaning apparatus, hydrogen peroxide was removed from the treated water through the catalyst column, passed through the microfiltration membrane, and then introduced into the treatment chamber, and the sample was washed for 2 hours. Table 6 shows values obtained by converting the increment of the measured sheet resistance value after cleaning with respect to the measured sheet resistance value before cleaning per hour.
- the concentration of hydrogen peroxide contained in the treated water at this time is 2 ⁇ g / L or less, the result of extracting a part of the treated water immediately before the treatment chamber and measuring the dissolved oxygen concentration is 6 ⁇ g / L, and the dissolved hydrogen concentration is 50 ⁇ g / L. Met.
- the dissolved oxygen concentration was reduced because dissolved oxygen was removed by the action of dissolved hydrogen and the catalyst, and the treatment inside the cleaning device suppressed the dissolution of air from the pipes and joints. It is thought that this is because
- the hydrogen peroxide concentration catalyst is reduced to 2 ⁇ g / L or less by passing hydrogen peroxide removal catalyst after hydrogen is added, and the substrate is washed with carbonated water having a reduced dissolved oxygen concentration. It is clear that the corrosion of copper can be suppressed by performing the above. It is obvious that the place for installing the hydrogen peroxide removal catalyst is in the immediate vicinity of the substrate processing apparatus, preferably in the substrate processing apparatus, more preferably in front of the processing chamber.
- Example 6 In the test of Example 5, nitrogen gas was introduced into the treatment chamber, and a cleaning test was performed under the condition that the oxygen gas concentration was 2% or less. The results are shown in Table 7.
- Example 7 By using the test line of Example 1 and controlling the amount of carbon dioxide added, carbonated water having a specific resistance of 0.03 to 10.0 M ⁇ ⁇ cm and a hydrogen peroxide concentration of 2 ⁇ g / L or less was obtained. The sample to be cleaned was replaced with a silicon wafer on which a thermal oxide film of 200 nm was formed, and each sample was cleaned for 2 hours, and then the surface potential was measured. A surface potential meter of Model 244 manufactured by Monro Electronics was used for the surface potential measurement. The results are shown in Table 8.
- the substrate when using ultrapure water containing carbonate with a hydrogen peroxide concentration of 2 ⁇ g / L or less, the substrate may not be charged if the specific resistance is in the range of 0.03 to 5.0 M ⁇ ⁇ cm. I understand.
- Substrate processing apparatus 1a Water inlet 2 of substrate processing apparatus 2 Hydrogen peroxide removal apparatus 3 Main piping 4 Carbon dioxide supply apparatus 5 Hydrogen supply apparatus 6 Membrane deaeration apparatus 10 Subsystem (secondary pure water system) 10a Subsystem water outlet 11 Hydrogen water supply system 11a Hydrogen water supply system water outlet 12 Carbonated water supply system 12a Carbonated water supply system water outlet
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Abstract
Description
図5は、本発明の第一実施形態に係る基板洗浄方法の態様を示す模式図である。サブシステムの水出口と各基板処理装置の水入口とは、半導体製造ラインに主に使われるPVCやPFA等からなる主配管を介して接続されている。基板処理装置1の中には処理室が設置されており(不図示)、洗浄水が供給されている。基板処理装置1は1つ以上あってもよく、各基板処理装置1の処理室についても1つ以上備えられていても良い。処理室には基板を保持する機構が設置されており、その機構は一枚の基板に炭酸水を吹きつけて処理する枚葉式、あるいは、炭酸水を貯留した槽内に複数の基板を浸漬して処理するバッチ式のいずれであってもよい。
前述の通り、予め水素を添加した水を白金族系金属触媒に通水すると、過酸化水素だけでなく溶存酸素も除去せしめることが可能となる。実施例にて詳述する通り、炭酸水を用いた基板の洗浄においても、炭酸水中の溶存酸素を除去すると銅の溶出が抑制されることが判明している。本実施形態はこのような知見に基づくものである。
図13は、本発明の第三実施形態に係る基板洗浄方法の態様を示す模式図である。図13に示すサブシステム10は図2から図4に示したものの何れかと同一であり、構成要素である紫外線酸化装置、非再生型イオン交換装置、膜分離装置および膜脱気装置は図から省略してある。サブシステムの水出口と各基板処理装置の水入口とは、半導体製造ラインに主に使われるPVCやPFA等からなる主配管を介して接続されている。基板処理装置1の中には処理室が設置されており(不図示)、洗浄水が供給されている。基板処理装置1は1つ以上あってもよく、各基板処理装置1の処理室についても1つ以上備えられていても良い。処理室には基板を保持する機構が設置されており、その機構は一枚の基板に炭酸水を吹きつけて処理する枚葉式、あるいは、炭酸水を貯留した槽内に複数の基板を浸漬して処理するバッチ式のいずれであってもよい。
図15は、本発明の第三実施形態に係る基板洗浄方法の態様を示す模式図である。図15に示すサブシステムは図2から図4に示したものの何れかと同一であり、構成要素である紫外線酸化装置、非再生型イオン交換装置、膜分離装置および膜脱気装置は図から省略してある。サブシステムの水出口と各基板処理装置の水入口とは、半導体製造ラインに主に使われるPVCやPFA等からなる主配管を介して接続されている。基板処理装置1の中には処理室が設置されており(不図示)、洗浄水が供給されている。基板処理装置1は1つ以上あってもよく、各基板処理装置1の処理室についても1つ以上備えられていても良い。処理室には基板を保持する機構が設置されており、その機構は一枚の基板に炭酸水を吹きつけて処理する枚葉式、あるいは、炭酸水を貯留した槽内に複数の基板を浸漬して処理するバッチ式のいずれであってもよい。
図18は、本発明の第五実施形態に係る基板洗浄方法の態様を示す模式図である。図18に示すサブシステムは図2から図4に示したものの何れかと同一であり、構成要素である紫外線酸化装置、非再生型イオン交換装置、膜分離装置および膜脱気装置は図から省略してある。サブシステムの水出口と各基板処理装置の水入口とは、半導体製造ラインに主に使われるPVCやPFA等からなる主配管を介して接続されている。基板処理装置1の中には処理室が設置されており、洗浄水が供給されている。基板処理装置1は1つ以上あってもよく、各基板処理装置1の処理室についても1つ以上備えられていても良い。処理室には基板を保持する機構が設置されており、その機構は一枚の基板に炭酸水を吹きつけて処理する枚葉式、あるいは、炭酸水を貯留した槽内に複数の基板を浸漬して処理するバッチ式のいずれであってもよい。
上述した過酸化水素除去装置2に使用される、過酸化水素除去および酸素除去が可能な触媒の具体例について詳述する。
当該触媒としては、白金族金属が担持された粒状のイオン交換樹脂、金属イオン型の粒状の陽イオン交換樹脂、白金族金属が担持された非粒状の有機多孔質体または白金族金属が担持された非粒状の有機多孔質イオン交換体が挙げられる。
白金族金属担持非粒状有機多孔質体としては、非粒状有機多孔質体に、平均粒子径1~1000nmの白金族金属の微粒子が担持されており、非粒状有機多孔質体が、連続骨格相と連続空孔相からなり、連続骨格の厚みは1~100μm、連続空孔の平均直径は1~1000μm、全細孔容積は0.5~50mL/gであり、白金族金属の担持量が、乾燥状態で0.004~20重量%である、白金族金属担持非粒状有機多孔質体が挙げられる。
イオン交換基を含まない油溶性モノマー、界面活性剤及び水の混合物を撹拌することにより油中水滴型エマルジョンを調製し、次いで油中水滴型エマルジョンを重合させて全細孔容積が16mL/gを超え、30mL/g以下の連続マクロポア構造のモノリス状の有機多孔質中間体(以下、モノリス中間体(1)とも記載する。)を得るI処理、
芳香族ビニルモノマー、一分子中に少なくとも2個以上のビニル基を有する全油溶性モノマー中、0.3~5モル%の架橋剤、芳香族ビニルモノマーや架橋剤は溶解するが芳香族ビニルモノマーが重合して生成するポリマーは溶解しない有機溶媒及び重合開始剤からなる混合物を調製するII処理、および
II処理で得られた混合物を静置下、且つI処理で得られたモノリス中間体(1)の存在下に重合を行い、共連続構造体である有機多孔質体であるモノリス(1)を得るIII処理、を含む。
(モノリス中間体の製造(I処理))
スチレン9.28g、ジビニルベンゼン0.19g、ソルビタンモノオレエート(以下SMOと略す)0.50gおよび2,2’-アゾビス(イソブチロニトリル)0.25gを混合し、均一に溶解させた。次に、当該スチレン/ジビニルベンゼン/SMO/2,2’-アゾビス(イソブチロニトリル)混合物を180gの純水に添加し、遊星式撹拌装置である真空撹拌脱泡ミキサー(イーエムイー社製)を用いて減圧下撹拌して、油中水滴型エマルションを得た。このエマルションを速やかに反応容器に移し、密封後静置下で60℃、24時間重合させた。重合終了後、内容物を取り出し、メタノールで抽出した後、減圧乾燥して、連続マクロポア構造を有するモノリス中間体を製造した。このようにして得られたモノリス中間体(乾燥体)の内部構造をSEMにより観察した。SEM画像から、隣接する2つのマクロポアを区画する壁部は極めて細く棒状であるものの、連続気泡構造を有しており、水銀圧入法により測定したマクロポアとマクロポアが重なる部分の開口(メソポア)の平均直径は40μm、全細孔容積は18.2mL/gであった。
次いで、スチレン216.6g、ジビニルベンゼン4.4g、1-デカノール220g、2,2’-アゾビス(2,4-ジメチルバレロニトリル)0.8gを混合し、均一に溶解させた(II処理)。次に上記モノリス中間体を反応容器に入れ、当該スチレン/ジビニルベンゼン/1-デカノール/2,2’-アゾビス(2,4-ジメチルバレロニトリル)混合物に浸漬させ、減圧チャンバー中で脱泡した後、反応容器を密封し、静置下50℃で24時間重合させた。重合終了後内容物を取り出し、アセトンでソックスレー抽出した後、減圧乾燥した(III処理)。
上記の方法で製造したモノリスをカラム状反応器に入れ、クロロスルホン酸1600gと四塩化スズ400g、ジメトキシメタン2500mLからなる溶液を循環・通液して、30℃、5時間反応させ、クロロメチル基を導入した。反応終了後、クロロメチル化モノリスをTHF/水=2/1の混合溶媒で洗浄し、更にTHFで洗浄した。このクロロメチル化モノリスにTHF1600mLとトリメチルアミン30%水溶液1400mLを加え、60℃、6時間反応させた。反応終了後、生成物をメタノールで洗浄し、次いで純水で洗浄してモノリスアニオン交換体を得た。
上記モノリスアニオン交換体をCl形にイオン交換した後、乾燥状態で円柱状に切り出し、減圧乾燥した。乾燥後のモノリスアニオン交換体の重量は、2.1gであった。この乾燥状態のモノリスアニオン交換体を、塩化パラジウム160mgを溶解した希塩酸に24時間浸漬し、塩化パラジウム酸形にイオン交換した。浸漬終了後、モノリスアニオン交換体を純水で数回洗浄し、ヒドラジン水溶液中に24時間浸漬して還元処理を行った。塩化パラジウム酸形モノリスアニオン交換体が茶色であったのに対し、還元処理終了後のモノリスアニオン交換体は黒色に着色しており、パラジウム微粒子の生成が示唆された。還元後の試料は、数回純水で洗浄した後、減圧乾燥させた。得られた乾燥状態のパラジウム微粒子担持触媒は内径57mmのカラムに層高が40mmとなるように充填し、水酸化ナトリウム水溶液を通液して担体であるモノリスアニオン交換体をOH形とした。また、イオン形を炭酸形とするときは炭酸水素アンモニウム水溶液を通液した。
洗浄処理される基板(サンプル)として、シリコンウエハに下地(支持層)としてチタンを予め50nmスパッタリングで成膜した上に、銅を200nmの厚みとなるようにスパッタリングで成膜した銅薄膜ウエハを、24mm角に切断したものを使用した。
使用した超純水は、オルガノ株式会社開発センター内に設置されている超純水製造装置の二次純水を使用した。超純水製造装置の出口での水質は次の表1のとおりである。
この試験は図21に示す試験ラインを用いて行った。超純水製造装置の二次純水(超純水)を触媒カラムを通して過酸化水素を除去せしめ、フィルター(精密濾過膜)を通した後、二酸化炭素溶解膜を用いて二酸化炭素を溶解して比抵抗を0.1MΩ・cmとした。このようにして作られた炭酸水を枚葉式洗浄装置内の処理室へ導入し、上記サンプルを2時間洗浄した。洗浄前のシート抵抗測定値に対する洗浄後のシート抵抗測定値の増分を、1時間当たりに換算した値を表2に示す。この時の処理水に含まれる過酸化水素濃度は2μg/L以下であった。また、枚葉式洗浄装置内の処理室直前にて処理水の一部を抜き出し、溶存酸素濃度を測定したところ30μg/Lであった。表1に示す通り超純水製造装置の出口での溶存酸素濃度は2μg/L以下であるが、PFA配管、継手部などでの空気の溶け込みにより、処理室直前では溶存酸素濃度が30μg/Lまで上昇したものと推察される。
この試験は、図21に示す試験ラインのうち触媒カラムとフィルターをバイパスする形で行った。超純水製造装置の二次純水(超純水)に二酸化炭素溶解膜を用いて二酸化炭素を溶解して比抵抗を0.1MΩ・cmとした。このようにして作られた炭酸水を枚葉式洗浄装置内の処理室へ導入し、上記サンプルを2時間洗浄した。洗浄前のシート抵抗測定値に対する洗浄後のシート抵抗測定値の増分を、1時間当たりに換算した値を表2に示す。この時の処理水に含まれる過酸化水素濃度は15μg/L、処理室直前での溶存酸素濃度は30μg/Lであった。
この試験は図23に示す試験ラインを用いて行った。超純水製造装置の二次純水(超純水)に酸素溶解膜を用いて所定の濃度の酸素ガスを溶解させた後、この酸素が溶解した水を触媒カラムを通して過酸化水素を除去せしめ、フィルター(精密濾過膜)を通し、二酸化炭素溶解膜を用いて二酸化炭素を溶解して比抵抗を0.1MΩ・cmとした。このようにして作られた炭酸水を枚葉式洗浄装置内の処理室へ導入し、上記サンプルを2時間洗浄した。洗浄前のシート抵抗測定値に対する洗浄後のシート抵抗測定値の増分を、1時間当たりに換算した値を表3に示す。この時の処理水に含まれる過酸化水素濃度は2μg/L以下であった。溶存酸素濃度については枚葉式洗浄装置内の処理室直前で処理水の一部を抜き出して測定を行った。
この試験は、図23に示す試験ラインのうち触媒カラムとフィルターをバイパスする形で行った。超純水製造装置の二次純水(超純水)に二酸化炭素溶解膜を用いて二酸化炭素を溶解して比抵抗を0.1MΩ・cmとした。このようにして作られた炭酸水を枚葉式洗浄装置内の処理室へ導入し、上記サンプルを2時間洗浄した。洗浄前のシート抵抗測定値に対する洗浄後のシート抵抗測定値の増分を、1時間当たりに換算した値を表3に示す。この時の処理水に含まれる過酸化水素濃度は15μg/Lであった。溶存酸素濃度については処理室直前で処理水の一部を抜き出して測定を行った。
実施例1の試験において、処理室に遮光を施して試験を行った。結果を表4に示す。
実施例1の試験において、処理室に窒素ガスを導入し、酸素ガス濃度を2%以下とした条件で洗浄試験を行った。結果を表5に示す。
この試験は、図24に示す試験ラインを用いて行った。超純水製造装置の二次純水(超純水)に水素溶解膜を用いて水素ガスを溶解させ、さらに二酸化炭素溶解膜を用いて二酸化炭素を溶解して比抵抗を0.1MΩ・cmとした。このようにして作られた炭酸水を枚葉式洗浄装置へ導入した。枚葉式洗浄装置の内部では、処理水を触媒カラムを通して過酸化水素を除去せしめ、精密濾過膜を通した後、処理室へ導入し、上記サンプルを2時間洗浄した。洗浄前のシート抵抗測定値に対する洗浄後のシート抵抗測定値の増分を、1時間当たりに換算した値を表6に示す。この時の処理水に含まれる過酸化水素濃度は2μg/L以下、処理室直前にて処理水の一部を抜き出して溶存酸素濃度を測定した結果は6μg/L、溶存水素濃度は50μg/Lであった。
実施例5の試験において処理室に窒素ガスを導入し、酸素ガス濃度を2%以下とした条件で洗浄試験を行った。結果を表7に示す。
実施例1の試験ラインを用い、二酸化炭素の添加量を制御することで比抵抗0.03~10.0MΩ・cm、過酸化水素濃度2μg/L以下の炭酸水を得た。洗浄するサンプルを熱酸化膜200nmが成膜されたシリコンウエハに代え、それぞれ2時間洗浄した後、表面電位を測定した。表面電位測定にはモンローエレクトロニクス社製モデル244の表面電位計を用いた。結果を表8に示す。
1a 基板処理装置の水入口
2 過酸化水素除去装置
3 主配管
4 二酸化炭素供給装置
5 水素供給装置
6 膜脱気装置
10 サブシステム(二次純水システム)
10a サブシステムの水出口
11 水素水供給システム
11a 水素水供給システムの水出口
12 炭酸水供給システム
12a 炭酸水供給システムの水出口
Claims (18)
- 水中に溶存する過酸化水素濃度が2μg/L以下に抑制され、かつ二酸化炭素を添加して比抵抗が0.03~5.0MΩ・cmの範囲に調整された炭酸水を用い、少なくとも銅または銅化合物が表面に露出した基板を洗浄することを含む、銅露出基板の洗浄方法。
- 前記炭酸水が、白金族系金属触媒に通水して前記過酸化水素濃度に抑制された炭酸水である、請求項1に記載の銅露出基板の洗浄方法。
- 前記白金族系金属触媒に通水する前に水素を添加することをさらに含む、請求項2に記載の銅露出基板の洗浄方法。
- 前記炭酸水の溶存酸素濃度を130μg/L以下に抑制することをさらに含む、請求項1から3のいずれか1項に記載の銅露出基板の洗浄方法。
- 前記白金族系金属触媒がパラジウム触媒である、請求項1から請求項4のいずれか1項に記載の銅露出基板の洗浄方法。
- 前記白金族系金属触媒が、パラジウム触媒をモノリス状有機多孔質アニオン交換体に担持したものである、請求項5に記載の銅露出基板の洗浄方法。
- 前記炭酸水を用いて前記基板を洗浄する工程を酸素ガス濃度2%以下の雰囲気下で行う、請求項1から6のいずれか1項に記載の銅露出基板の洗浄方法。
- 前記炭酸水を用いて前記基板を洗浄する工程を遮光された環境下で行う、請求項1から7のいずれか1項に記載の銅露出基板の洗浄方法。
- 水に紫外線を照射する紫外線酸化装置を含む超純水製造装置と、
少なくとも銅または銅化合物が表面に露出した基板が配置され、該基板を洗浄処理する基板処理液が供給される処理室と、
前記超純水製造装置の前記紫外線酸化装置から前記処理室の処理液吐出部までの流路において、水中に溶存する過酸化水素濃度が2μg/L以下に抑制され、かつ二酸化炭素を添加して比抵抗が0.03~5.0MΩ・cmの範囲に調整された炭酸水を前記基板処理液として作る手段と、
を備えた銅露出基板の洗浄システム。 - 前記手段は、水中から過酸化水素を除去する過酸化水素除去装置と、水中に二酸化炭素を供給する二酸化炭素供給装置とを含む、請求項9に記載の銅露出基板の洗浄システム。
- 前記過酸化水素除去装置は前記超純水製造装置内の前記紫外線酸化装置の下流に配置されており、前記二酸化炭素供給装置は前記超純水製造装置の水出口から前記処理室までの流路に配置されている、請求項10に記載の銅露出基板の洗浄システム。
- 前記紫外線酸化装置と前記過酸化水素除去装置の間の流路に水中に水素を添加する水素供給装置が配置されている、請求項11に記載の銅露出基板の洗浄システム。
- 前記過酸化水素除去装置と前記二酸化炭素供給装置が前記超純水製造装置の水出口から前記処理室までの流路に配置されている、請求項10に記載の銅露出基板の洗浄システム。
- 前記超純水製造装置の水出口から前記処理室までの流路において、前記過酸化水素除去装置の前段に水中に水素を添加する水素供給装置が配置されている、請求項13に記載の銅露出基板の洗浄システム。
- 前記過酸化水素除去装置は白金族系金属触媒が充填された触媒ユニットを有する、請求項9から14のいずれか1項に記載の銅露出基板の洗浄システム。
- 前記白金族系金属触媒がパラジウム触媒である、請求項15に記載の銅露出基板の洗浄システム。
- 前記白金族系金属触媒が、パラジウム触媒をモノリス状有機多孔質アニオン交換体に担持したものである、請求項15に記載の銅露出基板の洗浄システム。
- 前記処理室に供給する前記炭酸水は溶存酸素濃度が130μg/L以下に抑制されている、請求項15に記載の銅露出基板の洗浄システム。
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