JP4497909B2 - Method for regenerating glass substrate for mask blank, method for manufacturing mask blank, and method for manufacturing transfer mask - Google Patents

Description

  The present invention relates to a method for regenerating a glass substrate for mask blanks, in which a nitride film of metal silicide formed on a glass substrate such as a mask blank or a transfer mask is peeled off from the glass substrate to regenerate the glass substrate for mask blanks, and The present invention relates to a method for manufacturing a mask blank using the substrate and a method for manufacturing a transfer mask.

  For example, mask blanks, which are masters of transfer masks used when manufacturing LSIs and VLSIs, are used to form a thin film to be a transfer pattern on the surface of a precisely polished glass substrate by sputtering, and to pattern the thin film. The mask blanks are manufactured by forming the resist film by the same spin coating. With the recent miniaturization of patterns in semiconductor integrated circuits, halftone phase shift mask blanks are used as an effective pattern transfer technique for transferring a fine pattern. As halftone phase shift mask blanks, those described in Patent Document 1 have been proposed.

  The halftone phase shift mask blank proposed in Patent Document 1 is obtained by forming a metal silicide nitride film mainly containing metal, silicon, and nitrogen as a phase shift film on a glass substrate. This phase shift film is formed on a glass substrate by reactive sputtering in a mixed gas atmosphere in which an inert gas such as argon or xenon and a gas containing nitrogen are mixed using a sputtering target made of metal silicide. The phase shift film is controlled by adjusting the composition ratio of the sputter target and the flow rate of the gas containing nitrogen in the mixed gas so as to obtain a desired transmittance and phase difference. In particular, sputtering is performed in an atmosphere rich in nitrogen gas. When performing the above, defects such as particles and pinholes may occur in the phase shift film due to abnormal discharge.

  Mask blanks that have a predetermined size and a greater number of defects that affect the transfer pattern when manufacturing a halftone phase shift mask on a mask blank such as a halftone phase shift mask blank are discarded. It was common to dispose of it. This is because there is no guarantee that the phase shift film formed on the glass substrate can be completely peeled off without remaining film, and even if it can be completely peeled off, it cannot be guaranteed that the glass substrate has no influence on the optical characteristics. It is.

By the way, in recent years, miniaturization of patterns and shortening of the exposure wavelength have progressed, and with this, the glass substrate itself is required to have high quality and high surface flatness. It is becoming expensive. Under such circumstances, if all defective mask blanks are disposed of, the manufacturing cost becomes high and it is not preferable from the viewpoint of effective use of resources. Therefore, it is conceivable to recycle the glass substrate by peeling the thin film formed on the glass substrate of the defective mask blank with a peeling solution. In this case, as a stripping solution for stripping the phase shift film made of the above-described metal silicide nitride, it may be possible to use an etching solution used when etching these film materials. As an etching solution for etching the metal silicide film, one described in Patent Document 2 is known. That is, Patent Document 2 discloses at least one of ammonium hydrogen fluoride, ammonium fluoride, hydrofluoric acid, and boron fluoride as an etchant for etching a molybdenum silicide (molybdenum silicide) film. And an aqueous solution in which at least one of hydrogen peroxide and nitric acid is mixed.
Japanese Patent No. 2966369 JP 62-218585 A

  However, when a thin film (for example, molybdenum silicide nitride film) containing metal, silicon, and nitrogen as described in Patent Document 1 is peeled off using an etching solution as described in Patent Document 2 Since the etching rate of the thin film containing metal, silicon and nitrogen is slow, it takes a long time for the etching solution to contact the glass substrate until the thin film is completely removed, and the glass substrate on the back side where the thin film is not formed. The erosion becomes intense. Further, in the above-described etching solution, the etching selectivity between the thin film and the glass substrate cannot be taken so much that the surface of the glass substrate on which the thin film is formed may be eroded. Furthermore, in a region where defects in a thin film containing metal, silicon, and nitrogen exist, etching is not performed uniformly, and there are problems that the etching rate is high and low, and the glass substrate becomes rough. .

  If the front and back surfaces of the glass substrate are eroded at a predetermined level or more, there arises a problem that even if the glass substrate is uniformly eroded, the thickness of the glass substrate deviates from the standard and cannot be reused. In addition, a glass substrate having a rough surface needs to be precisely polished again. However, it has been found that this polishing generally requires a large polishing allowance, increases the polishing time and cost, and increases the possibility that the flatness of the peripheral portion of the substrate will deteriorate. In addition, when the amount of polishing is extremely large, there is a problem that the thickness of the glass substrate deviates from the standard. The present invention has been made in view of the above problems, and even when a thin film containing metal, silicon, and nitrogen is peeled off with a peeling solution, the glass substrate is prevented from being rough and reliably used for mask blanks. It is a first object to provide a method for regenerating a glass substrate for mask blanks that can regenerate a glass substrate. It is a second object of the present invention to provide a glass substrate for mask blanks that does not cause subfilm defects and a method for manufacturing the mask blanks using the regenerated glass substrate. It is a third object of the present invention to provide a transfer mask manufacturing method in which pattern defects due to subfilm defects do not occur.

As means for solving the above-mentioned problem, the first means is:
In the regeneration method of the glass substrate for mask blanks, the thin film formed on the glass substrate for mask blanks is peeled to regenerate the glass substrate for mask blanks.
The thin film mainly contains metal, silicon, and nitrogen,
For the peeling of the thin film, the glass substrate on which the thin film is formed is selected from at least one fluorine compound selected from hydrofluoric acid, hydrosilicofluoric acid, and ammonium hydrogen fluoride, hydrogen peroxide, nitric acid, and sulfuric acid. And a method for regenerating a glass substrate for mask blanks, which is performed by contacting with an aqueous solution containing 0.1 to 0.8 wt% of the fluorine compound.
The second means is
The method of regenerating a glass substrate for a mask blank according to the first means, wherein the temperature of the aqueous solution is 35 to 65 ° C.
The third means is
The method for regenerating a glass substrate for mask blanks according to the first or second means, wherein the content of nitrogen contained in the thin film is 5 to 60 atomic%.
The fourth means is
A method for producing a mask blank glass substrate, comprising: precisely polishing a surface of a mask blank glass substrate regenerated by a method for regenerating a mask blank glass substrate according to any one of the first to third means. .
The fifth means is
Manufacturing of a mask blank, characterized in that a thin film mainly containing metal, silicon and nitrogen is formed on the main surface of the glass substrate for mask blank obtained by the method for manufacturing a glass substrate for mask blank according to the fourth means. Is the method.
The sixth means is
A method for producing a transfer mask, comprising: patterning the thin film in a mask blank obtained by the method for producing a mask blank according to a fifth means to form a thin film pattern on the glass substrate.

  In the first means described above, when the aqueous solution is used, the concentration of a fluorine compound such as hydrofluoric acid, hydrosilicofluoric acid, or ammonium hydrogen fluoride is 0.1 to 0.8 wt%. These fluorine compounds function to preferentially etch a thin film and glass substrate containing metal, silicon and nitrogen. In this case, if the concentration is less than 0.1 wt%, the etching rate of the thin film with the aqueous solution becomes too slow and the peeling time becomes long, which is not preferable. On the other hand, if the concentration exceeds 0.8 wt%, the etching rate of the thin film with the aqueous solution becomes too fast, and the glass substrate after peeling becomes extremely rough, which is not preferable. In addition, an oxidizing agent such as hydrogen peroxide, nitric acid, sulfuric acid or the like acts to preferentially etch a thin film containing metal, silicon, and nitrogen while suppressing the erosion of the glass substrate, and accordingly, depending on the concentration of the fluorine compound. adjust.

  In practice, the concentration of an oxidizing agent such as a fluorine compound or hydrogen peroxide contained in the aqueous solution is determined in accordance with the material and composition of the thin film. When the content of metal and nitrogen contained in the thin film is large, the concentration of the fluorine compound contained in the aqueous solution is increased within the above range to ensure the peeling action, while the glass substrate is thereby damaged. To prevent this, increase the concentration of oxidizing agent. On the contrary, when the contents of metal and nitrogen are small, a large amount of silicon is contained in the thin film, so that the concentration of the fluorine compound is reduced within the above range. The aqueous solution may contain a surfactant in addition to the above-described fluorine compound and oxidizing agent. The surfactant is preferable because it acts to peel the thin film from the glass substrate uniformly in the surface.

  The glass substrate with a thin film referred to in the present invention is a mask blank in which a thin film containing metal, silicon and nitrogen is formed on one main surface of the glass substrate, and a thin film containing the metal, silicon and nitrogen. It refers to a transfer mask that has been patterned to form a thin film pattern. A representative example of the mask blank is a transmissive mask blank. The transmissive mask blank is a photomask blank or a phase shift mask blank in which a thin film (for example, a thin film having a light shielding function) that causes an optical change with respect to exposure light is formed on the surface of the glass substrate. It refers to a light shielding film that blocks exposure light, a phase shift film that changes the phase difference of exposure light, and the like.

  The contents of metal, silicon, and nitrogen contained in the thin film are optical characteristics that function as a light-shielding film and a phase shift film of the transmissive mask blank or as a reflective film in the reflective mask blank, respectively. Is adjusted as appropriate so that is obtained. As the metal, molybdenum, tungsten, tantalum, zirconium, nickel, or the like is used. In addition to nitrogen, oxygen, carbon, fluorine and the like can also be contained. The material of the glass substrate to be used is not particularly limited as long as it has high transmittance with respect to the exposure wavelength, such as synthetic quartz glass, soda lime glass, aluminosilicate glass, borosilicate glass, aluminoborosilicate glass. anything is fine.

  Moreover, the roughness of the surface of the glass substrate after peeling a thin film can be suppressed by making the temperature of aqueous solution into 35-65 degreeC like a 2nd means. By setting the temperature of the aqueous solution to the above temperature, the surface roughness of the glass substrate after peeling the thin film can be reduced to 30 nm or less at the maximum height Rmax, so that the load on the precision polishing process can be reduced. . The maximum height Rmax is defined by Japanese Industrial Standard JISB0601 (1994). Specifically, since it can be suppressed to about 0.03 times or less of the surface roughness obtained in the grinding process in the normal glass substrate manufacturing process, compared with the normal polishing process, the polishing process after the thin film peeling. The load can be reduced to about ½ or less. More specifically, the first-stage polishing (rough polishing) step can be omitted among the plurality of stages of polishing. In addition, since the polishing time can be shortened, deterioration of the flatness of the peripheral portion of the glass substrate can be suppressed, and a glass substrate with good flatness after polishing can be obtained, which is preferable. If the temperature of the aqueous solution is less than 35 ° C., the surface roughness of the glass substrate after peeling the thin film exceeds 50 nm at the maximum height Rmax, and the load of the precision polishing process cannot be reduced, and the flatness deteriorates. It is not preferable. On the other hand, if it exceeds 65 ° C., the concentration of the etching solution (peeling solution) changes due to evaporation of the aqueous solution, which is not preferable.

  The content of nitrogen contained in the thin film is preferably 5 to 60 atomic% as in the third means. If it is this composition range, the thin film on a glass substrate can be easily peeled from a glass substrate without a film residue. Also, as in the fourth means, the thin film is peeled off from the glass substrate with an aqueous solution and then precisely polished to completely remove the film residue and to ensure the surface roughness and optical characteristics (transmittance) of the glass substrate. Can be as desired. In this case, the precision polishing method is not particularly limited. Either single-side polishing for polishing one side of the glass substrate or double-side polishing for polishing both surfaces of the glass substrate at one time may be used. The precision polishing is preferably performed in a plurality of stages so that the surface roughness gradually decreases in order to ensure a predetermined surface roughness. In this case, the average particle size of the abrasive used is reduced as the polishing step proceeds, and the final surface roughness of the glass substrate after precision polishing is a maximum height Rmax of 2 nm or less and a flatness of 1 μm or less. To be. For multiple stages of precision polishing, a soft polisher is used as the polishing pad, and the polishing agent is selected from cerium oxide, zirconium oxide, aluminum oxide, manganese oxide, colloidal silica, and the average particle size of the polishing agent is It adjusts suitably in the range of 0.03-3 micrometers.

  Moreover, when manufacturing a mask blank, the method of forming the thin film mainly containing a metal, a silicon | silicone, and nitrogen on the glass substrate for mask blanks is not specifically limited. Examples include a sputtering method, a CVD method, and a vacuum deposition method. A reactive sputtering method in which a sputtering target containing metal and silicon is used and sputtering is performed in an atmosphere containing nitrogen gas is preferable. Moreover, when manufacturing the transfer mask from mask blanks, the method of forming a thin film pattern on the glass substrate for mask blanks is not specifically limited. A resist pattern is formed on the thin film, and the resist pattern is used as a mask to form a thin film pattern. Alternatively, a resist pattern is formed on a glass substrate for mask blanks in advance, and a thin film is formed thereon. Thus, a so-called lift-off method for forming a thin film pattern may be used. The former is preferable from the viewpoint of forming a fine pattern.

  According to the above-described means, even when a thin film containing metal, silicon, and nitrogen is peeled off with a stripping solution, the glass substrate for mask blanks can be reliably regenerated by suppressing the roughness of the glass substrate. In addition, it becomes possible to easily obtain a glass substrate for mask blanks in which no subsurface defects occur, and a transfer mask in which pattern defects due to subfilm defects do not occur, using the regenerated glass substrate.

Hereinafter, a method for regenerating a glass substrate for a mask blank according to Example 1 of the present invention, a method for manufacturing a mask blank, and a method for manufacturing a transfer mask will be described with an example of regenerating a glass substrate of a halftone phase shift mask blank To do.
(1) Manufacture of halftone phase shift mask blanks On a synthetic quartz glass substrate whose surface roughness was mirror-polished to a maximum height (Rmax) of 2 nm or less by measuring the roughness with an atomic force microscope, A halftone phase shift mask in which a molybdenum silicide nitride film is formed on a glass substrate by sputtering in a mixed gas atmosphere of argon gas and nitrogen gas using a mixed target of molybdenum and silicon by a DC magnetron sputtering method. Blanks were obtained. The film thickness of the molybdenum silicide nitride film formed on the glass substrate is about 850 angstroms, and the film composition (average value of the whole) is Mo: 12.5 at%, Si: 40.2 at%, N: 47. 3 at% (ESCA analysis).

(2) Surface defect inspection When the obtained half-tone type phase shift mask blanks are inspected with a surface defect inspection apparatus, a convex shape that seems to have foreign matters interposed between the glass substrate and the molybdenum silicide nitride film. I found a subfilm defect. Such subfilm defects cannot be corrected in subsequent processes. Therefore, the molybdenum silicide nitride film was removed by the following method to regenerate the glass substrate.

(3) Regeneration of glass substrate As an aqueous solution, a mixed aqueous solution of ammonium hydrogen fluoride (0.5 wt%) + hydrogen peroxide (2.0 wt%) + pure water (97.5 wt%) is used, and molybdenum silicide is obtained by an immersion method. The nitride film was peeled from the glass substrate. The temperature of the stripping solution at this time was 40 ° C., the treatment time was 30 minutes, and the glass substrate was rocked during the treatment. When the surface of the glass substrate from which the molybdenum silicide nitride film was peeled was confirmed by composition analysis using AES (Auger Electron Spectroscopy), no residue of the molybdenum silicide nitride film was confirmed. Moreover, the surface roughness of the peeled glass substrate was 18 nm at the maximum height (Rmax). By precisely polishing the glass substrate surface, the glass substrate for mask blanks was obtained by setting the surface roughness of the glass substrate to 2 nm or less at the maximum height Rmax. Precision polishing is performed with a double-side polishing machine by supplying a cerium sulfide abrasive with an average particle size of 1 μm between a suede type polishing pad and a glass substrate, and then polishing between the suede type polishing pad and the glass substrate. A colloidal silica abrasive having an average particle size of 100 μm was supplied to the substrate to carry out polishing in two stages. The processing load and polishing time for precision polishing were appropriately adjusted so as to obtain a desired surface roughness.

(4) Reproduction of halftone phase shift mask blanks Using this regenerated glass substrate, a molybdenum silicide nitride film is again formed on the glass substrate by DC magnetron sputtering, and a halftone phase shift mask is obtained. Blanks were obtained. When the obtained half-toned phase shift mask blanks were inspected with a surface defect inspection apparatus, the above-mentioned convex subfilm defects were not confirmed. A resist was coated on the halftone phase shift mask blank having no subfilm defects, and a resist pattern was formed by drawing. Using this resist pattern as a mask, a molybdenum silicide nitride film was formed by dry etching using a fluorine gas to form a halftone film pattern made of a molybdenum silicide nitride film on a glass substrate to obtain a halftone phase shift mask. When the pattern defect and the phase defect were confirmed about the obtained halftone type phase shift mask, neither defect was confirmed.

  Next, in Example 1 described above, the temperature (treatment time) of the aqueous solution during treatment was 30 (60 minutes) ° C., 50 ° C. (30 minutes), 65 ° C. (25 minutes), and 70 ° C. (20 minutes). Except for the change, the molybdenum silicide nitride film was peeled off from the glass substrate in the same manner as in Example 1. As a result, when the temperature of the aqueous solution was 30 ° C., the surface roughness of the glass substrate after peeling was 90 nm at the maximum height Rmax, and the surface roughness was deteriorated. When the temperature of the aqueous solution was 35 ° C. or higher, the maximum height Rmax became 30 nm or less. However, when the temperature exceeded 70 ° C., the concentration changed to a degree that could not be ignored due to evaporation of the aqueous solution.

Next, in Example 1 described above, the glass substrate was regenerated in the same manner as in Example 1 except that the respective concentrations of ammonium hydrogen fluoride and hydrogen peroxide were changed. It shows in Table 1 as Comparative Examples 1-4 . Examples 7 to 14 are shown in Table 2 in which hydrofluoric acid and silicohydrofluoric acid are used in place of ammonium hydrogen fluoride, and the respective concentrations are similarly changed. From Tables 1 and 2, the following can be understood. By using an aqueous solution containing 0.1 to 0.8 wt% of a fluorine compound, the glass substrate of the halftone phase shift mask blank can be reproduced satisfactorily. On the other hand, if the concentration of the fluorine compound is less than 0.1 wt%, the etching rate of the thin film with the aqueous solution becomes too slow and the peeling time becomes long, which is not preferable. On the other hand, if the concentration exceeds 0.8 wt%, the etching rate of the thin film with the aqueous solution becomes too fast, and the glass substrate after peeling becomes extremely rough, which is not preferable.

  In the present invention, a nitride film of metal silicide formed on a glass substrate such as a mask blank or a transfer mask is peeled off from the glass substrate to regenerate the mask blank glass substrate, and the mask blank or transfer material using the substrate is regenerated. It can be used when manufacturing a mask.

Claims (6)

In the method for regenerating a glass substrate for mask blanks by peeling the thin film formed on the glass substrate for mask blanks and regenerating the glass substrate for mask blanks,
The thin film mainly contains metal, silicon, and nitrogen,
For the peeling of the thin film, the glass substrate on which the thin film is formed is selected from at least one fluorine compound selected from hydrofluoric acid, hydrosilicofluoric acid, and ammonium hydrogen fluoride, hydrogen peroxide, nitric acid, and sulfuric acid. A method for regenerating a glass substrate for mask blanks, comprising: contacting with an aqueous solution containing 0.5 to 0.8 wt% of the fluorine compound.
  The method for regenerating a glass substrate for a mask blank according to claim 1, wherein the temperature of the aqueous solution is 35 to 65 ° C.   The method for regenerating a glass substrate for mask blanks according to claim 1 or 2, wherein the content of nitrogen contained in the thin film is 5 to 60 atomic%.   A method for producing a glass substrate for mask blanks, comprising precisely polishing the surface of the glass substrate for mask blanks regenerated by the method for regenerating a glass substrate for mask blanks according to any one of claims 1 to 3.   5. A mask blank manufacturing method comprising: forming a thin film mainly containing metal, silicon and nitrogen on a main surface of a glass substrate for mask blank obtained by the method for manufacturing a glass substrate for mask blank according to claim 4. Method.   A method for producing a transfer mask, comprising: patterning the thin film in a mask blank obtained by the method for producing a mask blank according to claim 5 to form a thin film pattern on the glass substrate.