JP2008095203A - Electrolytic copper plating method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electrolytic copper plating method for a semiconductor wafer where, upon electrolytic copper plating, the generation of particles such as sludge generated on the anode side in a plating liquid is suppressed, and the sticking of particles to a semiconductor wafer is prevented; to provide a phosphorous-containing copper anode for electrolytic copper plating; and to provide a semiconductor wafer plated using them and having reduced sticking of particles. <P>SOLUTION: Regarding the electrolytic copper plating method, upon electrolytic copper plating, as an anode, phosphorous-containing copper is used, and when anode current density upon the electrolysis is ≥3 A/dm<SP>2</SP>, the crystal grain diameter of the phosphor-containing copper anode 4 is controlled to 10 to 1,500 μm, and when anode current density upon the electrolysis is <3 A/dm<SP>2</SP>, the crystal grain size of the phosphorus-containing copper anode is controlled to 5 to 1,500 μm. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention suppresses generation of particles such as sludge generated on the anode side in a plating bath during electrolytic copper plating, and in particular, prevents electrolytic particles from adhering to a semiconductor wafer. The present invention relates to a phosphorous copper anode and a semiconductor wafer with less particle adhesion, which is electroplated using these.

 In general, electrolytic copper plating is used for forming a copper wiring in a PWB (printed wiring board) or the like, but has recently been used for forming a copper wiring of a semiconductor. Electro-copper plating has a long history, and has accumulated a lot of technology, and has come to the present day. However, when this electro-copper plating is used for forming a copper wiring of a semiconductor, there is a new inconvenience that was not a problem with PWB. It came out.

Usually, when performing electrolytic copper plating, phosphorous copper is used as an anode. This is because when an insoluble anode made of platinum, titanium, iridium oxide or the like is used, the additive in the plating solution is decomposed due to the influence of the anodic oxidation, resulting in poor plating. When copper or oxygen-free copper is used, a large amount of particles such as sludge made of metallic copper or copper oxide resulting from the disproportionation reaction of monovalent copper during dissolution will contaminate the object to be plated. It is.
In contrast, when a phosphorous copper anode is used, a black film made of copper phosphide, copper chloride, or the like is formed on the anode surface by electrolysis, and metal copper or copper oxide is formed by the disproportionation reaction of monovalent copper. Generation can be suppressed and generation of particles can be suppressed.

However, even if phosphorus-containing copper is used as the anode as described above, the generation of particles cannot be completely suppressed because there is a drop of the black film or the formation of metallic copper or copper oxide in the thin part of the black film. Absent.
For this reason, the anode is usually wrapped with a filter cloth called an anode bag to prevent particles from reaching the plating solution.
However, when such a method is applied particularly to plating on a semiconductor wafer, fine particles that did not become a problem in the formation of wiring on the PWB or the like as described above reach the semiconductor wafer and adhere to the semiconductor. As a result, a problem that caused plating defects occurred.

 The present invention suppresses the generation of particles such as sludge generated on the anode side in a plating solution when performing electrolytic copper plating, and in particular prevents electrolytic particles from adhering to a semiconductor wafer. It is an object of the present invention to provide a phosphorous copper anode and a semiconductor wafer with less particle adhesion, which is electroplated using these.

In order to solve the above-mentioned problems, the present inventors have conducted intensive research, and as a result, by improving the material of the electrode and suppressing the generation of particles at the anode, a semiconductor wafer having less particle adhesion can be stably produced. The knowledge that it can manufacture was acquired.
The present invention is based on this finding,
1. When performing electrolytic copper plating, when phosphorous copper is used as an anode and the anode current density during electrolysis is 3 A / dm ² or more, the crystal grain size of the phosphorous copper anode is set to 10 to 1500 μm, and during electrolysis of the case where the anode current density is less than 3A / dm ^2, the electrolytic copper plating method 2 and performing electrolytic copper plating using an anode in which the crystal grain size of the phosphorous copper anode and 5～1500Myuemu. When performing electrolytic copper plating, when phosphorous copper is used as an anode and the anode current density during electrolysis is 3 A / dm ² or more, the crystal grain size of the phosphorous copper anode is set to 20 to 700 μm, and during electrolysis When the anode current density is less than 3 A / dm ² , electrolytic copper plating is performed using an anode in which the phosphorous copper anode has a crystal grain size of 10 to 700 μm. 3. The electrolytic copper plating method according to 1 or 2 above, wherein the phosphorus content of the phosphorous copper anode is 50 to 2000 wtppm. 4. When performing electrolytic copper plating, while using phosphorous copper as the anode, a fine crystal layer having a crystal grain size of 1 to 100 μm is formed in advance on the surface of the phosphorous copper anode. When performing electrolytic copper plating, while using phosphorous copper as an anode, a fine crystal layer having a crystal grain size of 1 to 100 μm is formed in advance on the surface of the phosphorous copper anode. 5. The electrolytic copper plating method described The electrolytic copper plating method according to each of the above 1 to 3 or 5, wherein the surface of the phosphorous copper-containing anode has a black film layer having a thickness of 1000 μm or less mainly composed of copper phosphide and copper chloride. .

The present invention also provides
7). 7. An anode for electrolytic copper plating, wherein phosphorous copper is used as the anode, and the phosphorous copper anode has a crystal grain size of 5 to 1500 μm. 8. A phosphorous copper anode for electrolytic copper plating, comprising: an anode for electrolytic copper plating, wherein phosphorous copper is used as an anode, and the crystal grain size of the phosphorous copper anode is 10 to 700 μm. 9. The phosphorus-containing copper anode for electrolytic copper plating as described in 7 or 8 above, wherein the phosphorus content of the phosphorus-containing copper anode is 50 to 2000 wtppm. An anode for electrolytic copper plating, using phosphorous copper as an anode, and having a fine crystal layer having a crystal grain size of 1 to 100 μm formed in advance on the surface of the phosphorous copper anode 10. Phosphorus copper anode for plating An anode for electrolytic copper plating, wherein phosphorous copper is used as the anode, and has a fine crystal layer having a crystal grain size of 1 to 100 μm formed in advance on the surface of the phosphorous copper anode. 11. Phosphorus-containing copper anode for electrolytic copper plating according to each of items 9 to 12. The phosphorous copper for electrolytic copper plating according to each of the above 7 to 9 or 11, wherein the phosphorous copper anode surface has a black film layer having a thickness of 1000 μm or less mainly composed of copper phosphide and copper chloride. Anode 13. The electrolytic copper plating method and the phosphorous copper anode for electrolytic copper plating according to each of 1 to 12 above, wherein the electrolytic copper plating is performed on a semiconductor wafer.
The present invention further provides 14. A semiconductor wafer with less particle adhesion plated using the electrolytic copper plating method and the phosphorous copper anode for electrolytic copper plating described in each of 1 to 13 above is provided.

 The present invention has an excellent effect that, when electrolytic copper plating is performed, generation of particles due to sludge or the like generated on the anode side in the plating solution can be suppressed, and adhesion of particles to the semiconductor wafer can be extremely reduced.

 FIG. 1 shows an example of an apparatus used for a method for electrolytic copper plating of a semiconductor wafer. The copper plating apparatus includes a plating tank 1 having a copper sulfate plating solution 2. An anode 4 made of a phosphorous copper anode is used as the anode, and the cathode is a semiconductor wafer for plating, for example.

As described above, when phosphorous copper is used as an anode during electroplating, a black film mainly composed of copper phosphide and copper chloride is formed on the surface, and the monovalent when the anode is dissolved It has a function of suppressing the generation of particles such as sludge composed of metallic copper, copper oxide or the like due to copper disproportionation reaction.
However, the black film production rate is strongly influenced by the anode current density, crystal grain size, phosphorus content, etc., and the higher the current density, the smaller the crystal grain size, and the higher the phosphorus content rate, the faster it becomes. As a result, it was found that the black film tends to be thick.
Conversely, the lower the current density, the larger the crystal grain size, and the lower the phosphorus content, the slower the production rate, and as a result, the black film becomes thinner.
As described above, the black film has a function of suppressing the generation of particles such as metallic copper and copper oxide. However, if the black film is too thick, it is peeled off and caused itself to generate particles. A big problem arises. On the other hand, if it is too thin, there is a problem that the effect of suppressing the production of metallic copper, copper oxide and the like is reduced.
Therefore, in order to suppress the generation of particles from the anode, it is extremely important to optimize each of the current density, crystal grain size, and phosphorus content to form a stable black film with an appropriate thickness. I understand.

The present invention proposes a phosphorous copper anode exhibiting the above optimum values. When the anode current density during electrolysis is 3 A / dm ² or more, the phosphorus-containing copper anode of the present invention has a crystal grain size of 10 to 1500 μm, preferably 20 to 700 μm. When the current density is less than 3 A / dm ² , the phosphor-containing copper anode has a crystal grain size of 5 to 1500 μm, preferably 10 to 700 μm.
Furthermore, it is desirable that the phosphorus content of the phosphorus-containing copper anode is 50 to 2000 wtppm as an appropriate composition ratio for suppressing the generation of particles.
By using the phosphorus-containing copper anode, a black film layer having a thickness of 1000 μm or less mainly composed of copper phosphide and copper chloride can be formed on the surface of the phosphorus-containing copper anode at the time of electrolytic copper plating.

Usually, the anode current density when performing electrolytic copper plating is 1 to 5 A / dm ^2. However, when a new anode in which a black film is not formed is to be electrolyzed at a high current density from the initial stage of electrolysis, adhesion Since a black film with good properties cannot be obtained, it is necessary to perform the electrolysis for several hours to one day at a current density as low as about 0.5 A / dm ² before entering the main electrolysis.
However, since such a process is inefficient, when performing electrolytic copper plating, a fine crystal layer having a crystal grain size of 1 to 100 μm is formed in advance on the surface of the phosphorous-containing copper anode, and then electrolysis is performed. Thus, it is possible to shorten the time of weak electrolysis that takes a long time, and to increase production efficiency.
Of course, when using a phosphorous copper anode in which a black film having a predetermined thickness is formed in advance, the preliminary treatment by the weak electrolysis as described above is unnecessary.
Thus, by performing electrolytic copper plating using the phosphorous-containing copper anode of the present invention, generation of sludge and the like can be remarkably reduced, particles reach the semiconductor wafer, and adhere to the semiconductor wafer. This eliminates the possibility of plating defects.
Electro copper plating using the phosphorous-containing copper anode of the present invention is particularly useful for plating on semiconductor wafers, but also reduces the rate of defective plating due to particles in copper plating in other fields where thinning is progressing. It is effective as a method.

As described above, the phosphorus-containing copper anode of the present invention has the effect of suppressing mass generation of particles such as sludge made of metallic copper or copper oxide, and significantly reducing contamination of the object to be plated. There is no occurrence of decomposition of the additive in the plating solution and plating failure caused by the use.
As a plating solution, copper sulfate: 10-70 g / L (Cu), sulfuric acid: 10-300 g / L, chlorine ion 20-100 mg / L, additive: (Nikko Metal Plating CC-1220: 1 mL / L, etc.) The proper amount can be used. Further, the purity of copper sulfate is desirably 99.9% or more.
In addition, the plating bath temperature is 15 to 35 ° C., the cathode current density is 0.5 to 5.5 A / dm ² , the anode current density is 0.5 to 5.5 A / dm ² , and the plating time is 0.5 to 100 hr. desirable. Although the suitable example of plating conditions is shown above, it does not necessarily need to be restrict | limited to said conditions.

  Next, examples of the present invention will be described. In addition, a present Example is an example to the last, and is not restrict | limited to this example. That is, all aspects or modifications other than the embodiments are included within the scope of the technical idea of the present invention.

(Examples 1-4)
As shown in Table 1, phosphorus-containing copper having a phosphorus content of 300 to 600 wtppm was used as the anode, and a semiconductor wafer was used as the cathode. The crystal grain size of these phosphorous copper anodes was 10 to 200 μm.
As a plating solution, copper sulfate: 20 to 55 g / L (Cu), sulfuric acid: 10 to 200 g / L, chlorine ion 60 mg / L, additive [brightening agent, surfactant] (manufactured by Nikko Metal Plating Co., Ltd .: trade name) CC-1220): 1 mL / L was used. The purity of copper sulfate in the plating solution was 99.99%.
The plating conditions are a plating bath temperature of 30 ° C., a cathode current density of 1.0 to 5.0 A / dm ² , an anode current density of 1.0 to 5.0 A / dm ² , and a plating time of 19 to 96 hours. The above conditions are shown in Table 1.

After plating, the amount of particles generated and the appearance of plating were observed. The results are also shown in Table 1.
In addition, the amount of particles was obtained by filtering the plating solution with a 0.2 μm filter after the electrolysis and measuring the weight of the filtrate.
In addition, after the electrolysis, the plating appearance was changed by replacing the object to be plated, and plating was performed for 3 minutes, and the presence or absence of burns, fogging, blistering, abnormal precipitation, foreign matter adhesion, etc. was visually observed.
As a result, in Examples 1 to 4, the amount of particles was less than 1 mg, and the plating appearance was good.

(Examples 5 to 8)
As shown in Table 2, phosphorus-containing copper having a phosphorus content of 500 wtppm was used as the anode, and a semiconductor wafer was used as the cathode. The crystal grain size of these phosphorous copper anodes was 200 μm.
As a plating solution, copper sulfate: 55 g / L (Cu), sulfuric acid: 10 g / L, chlorine ion 60 mg / L, additive [brightener, surfactant] (manufactured by Nikko Metal Plating Co., Ltd .: trade name CC-1220) 1 mL / L was used. The purity of copper sulfate in the plating solution was 99.99%.
The plating conditions are a plating bath temperature of 30 ° C., a cathode current density of 1.0 to 5.0 A / dm ² , an anode current density of 1.0 to 5.0 A / dm ² , and a plating time of 24 to 48 hr.
Examples 5 to 8 show examples in which a fine crystal layer having a crystal grain size of 5 μm and 10 μm is formed in advance on the surface of the anode in a thickness of 100 μm, and a black film is formed in 100 μm and 200 μm.
The above conditions are shown in Table 2.

After plating, the amount of particles generated and the appearance of plating were observed. The results are also shown in Table 2. Note that the amount of particles and the appearance of plating are observed by the same method as in Examples 1 to 4 above.
As a result, in Examples 5 to 8, the amount of particles was less than 1 mg, and the plating appearance was good.
Further, as shown in Table 2, compared to Examples 1 to 4, predetermined plating was obtained in a short time even at a relatively low current density. This is considered to be due to the fact that a fine crystal layer with a crystal grain size of 5 μm and 10 μm was formed on the surface of the anode in advance with a thickness of 100 μm and a black film was formed with 100 μm and 200 μm.
Therefore, forming a fine crystal layer or a black film layer having a crystal grain size of 1 to 100 μm formed in advance on the surface of the phosphorous copper anode is effective for forming a stable plating film free of particles in a short time. I understand that there is.

(Comparative Examples 1-4)
As shown in Table 3, phosphorus-containing copper having a phosphorus content of 500 wtppm was used as the anode, and a semiconductor wafer was used as the cathode. The crystal grain sizes of these phosphorous copper anodes were 3 μm or 2000 μm, which are outside the scope of the present invention.
As a plating solution, copper sulfate: 55 g / L (Cu), sulfuric acid: 10 g / L, chlorine ion 60 mg / L, additive [brightener, surfactant] (manufactured by Nikko Metal Plating Co., Ltd .: trade name CC-1220) 1 mL / L was used. The purity of copper sulfate in the plating solution was 99.99%.
The plating conditions are a plating bath temperature of 30 ° C., a cathode current density of 1.0 to 5.0 A / dm ² , an anode current density of 1.0 to 5.0 A / dm ² , and a plating time of 19 to 96 hours. The above conditions are shown in Table 3.

After plating, the amount of particles generated and the appearance of plating were observed. The results are also shown in Table 3.
The amount of particles and the appearance of plating were measured and observed under the same conditions as in the above examples. As a result, in Comparative Examples 1 to 3, the amount of particles reached 425 to 2633 mg, and the plating appearance was poor.
Thus, it has been confirmed that the generation of particles increases when the crystal grain size of the phosphorous copper anode is excessively large or too small. Therefore, it can be seen that optimization of the phosphorous copper anode is important.

 Since the present invention has an excellent effect of suppressing the generation of particles due to sludge and the like generated on the anode side in the plating solution when performing electrolytic copper plating, the adhesion of particles to the semiconductor wafer can be extremely reduced. It is useful for forming copper wiring such as PWB (printed wiring board).

It is a conceptual diagram of the apparatus used in the electrolytic copper plating method of the semiconductor wafer of this invention.

Explanation of symbols

1 Plating tank 2 Copper sulfate plating solution 3 Semiconductor wafer 4 Phosphorus copper anode

Claims (14)

When performing electrolytic copper plating, when phosphorous copper is used as an anode and the anode current density during electrolysis is 3 A / dm ² or more, the crystal grain size of the phosphorous copper anode is set to 10 to 1500 μm, and during electrolysis When the anode current density is less than 3 A / dm ² , the copper electroplating is performed using an anode in which the phosphorous copper anode has a crystal grain size of 5 to 1500 μm. When performing electrolytic copper plating, when phosphorous copper is used as an anode and the anode current density during electrolysis is 3 A / dm ² or more, the crystal grain size of the phosphorous copper anode is set to 20 to 700 μm, and during electrolysis When the anode current density is less than 3 A / dm ² , the copper electroplating is performed using an anode in which the phosphorous copper anode has a crystal grain size of 10 to 700 μm. 3. The electrolytic copper plating method according to claim 1, wherein the phosphorus content of the phosphorous copper anode is 50 to 2000 wtppm. A copper electroplating method, wherein phosphorous copper is used as an anode when performing electrocopper plating, and a fine crystal layer having a crystal grain size of 1 to 100 μm is formed in advance on the surface of the phosphorous copper anode. Each of Claims 1-3 characterized by using phosphorous copper as an anode when performing electrolytic copper plating and forming a fine crystal layer having a crystal grain size of 1 to 100 μm in advance on the surface of the phosphorous copper anode. The electrolytic copper plating method described in 1. 6. The electrolytic copper plating method according to claim 1, wherein the surface of the phosphorous copper-containing anode has a black film layer having a thickness of 1000 [mu] m or less mainly composed of copper phosphide and copper chloride. An anode for electrolytic copper plating, wherein phosphorous copper is used as an anode, and the phosphorous copper anode has a crystal grain size of 5 to 1500 μm. A phosphorous copper anode for electrolytic copper plating, comprising: an anode for electrolytic copper plating, wherein phosphorous copper is used as the anode, and the crystal grain size of the phosphorous copper anode is 10 to 700 μm. The phosphorous copper anode for electrolytic copper plating according to claim 7 or 8, wherein the phosphorous content of the phosphorous copper anode is 50 to 2000 wtppm. An anode for electrolytic copper plating, using phosphorous copper as an anode, and having a fine crystal layer having a crystal grain size of 1 to 100 μm formed in advance on the surface of the phosphorous copper anode Phosphorus copper anode for plating. An anode for performing electrolytic copper plating, wherein phosphorous copper is used as the anode, and has a fine crystal layer having a crystal grain size of 1 to 100 μm formed in advance on the surface of the phosphorous copper anode. The phosphorous copper anode for electrolytic copper plating as described in each of 7-9. The phosphorus-containing electrode for copper electroplating according to claim 7, wherein the phosphor-containing copper anode surface has a black film layer having a thickness of 1000 μm or less mainly composed of copper phosphide and copper chloride. Copper anode. The copper electroplating method and the phosphorous copper anode for electrolytic copper plating according to each of claims 1 to 12, wherein the copper electroplating is performed on a semiconductor wafer. A semiconductor wafer with less particle adhesion plated using the electrolytic copper plating method according to claim 1 and the phosphorous copper anode for electrolytic copper plating.

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