JP2010037659A - Casting mold composed of anodized porous alumina, and method for manufacturing the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a casting mold composed of anodized porous alumina capable of efficiently forming a desired antireflection film on a high polymer film surface, and to provide a method for manufacturing the casting mold. <P>SOLUTION: The method for manufacturing the casting mold composed of the anodized porous alumina comprises: (1) a step of forming pores by subjecting an aluminum substrate to anodization; (2) a step of subjecting the pores to a pore size expansion treatment; (3) a step of subjecting the substrate again to anodization after the step (2); and (4) a step of alternately repeating the step (2) and the step (3). <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a mold made of anodized porous alumina for forming an antireflection layer (antireflection film) which is formed on the surface of a polymer film (film) and reduces reflection in the visible light region, and a method for producing the same.

  In various display devices for information equipment, polymer films are widely used. However, in order to ensure good visibility, it is necessary to form an antireflection layer for suppressing reflected light. Usually, a multilayer film composed of dielectrics having different refractive indexes is used as the antireflection layer. However, a vacuum deposition method or a sputtering method is used to form the dielectric layer, and the reflection layer The layer formation has a problem of requiring an expensive apparatus and a great production time.

  On the other hand, a method is known in which the reflectance is reduced by providing a protrusion-like shape on the surface of the polymer film and forming a layer whose refractive index continuously changes. In order to impart a protrusion shape to the polymer film, a method is generally used in which a stamper having a depression array corresponding to the protrusion shape is prepared and the polymer film is processed based on the stamper.

  The depression formed in the stamper for forming the protrusion shape on the surface of the polymer film has a fine period compared to the wavelength of light, and in order to sufficiently attenuate the reflectance in the visible light region, It is necessary to have a depth of about 1/4 (for example, Patent Document 1). At this time, the recess needs to have a tapered shape because it is necessary to continuously change the refractive index.

  In order to form a hollow array that satisfies such conditions, a technique that combines electron beam lithography or patterning by light exposure and anisotropic etching of a semiconductor single crystal typified by Si is generally used. In this method, an opening having a desired period is formed by various lithography, and then a tapered hole is formed by a wet or dry etching method. As a lithography method, electron beam lithography is capable of patterning with a sufficiently fine period, but requires a great deal of time and an expensive apparatus for processing. In the light exposure method, a method of forming a pattern by using interference of laser light is used, but it is difficult to form a structure having a sufficiently fine period.

  As a method for forming a fine pattern, a method using anodized porous alumina having a regular pore arrangement has been proposed (for example, Non-Patent Document 1). In this method, a recess is formed in the Si substrate by performing reactive ion etching using anodized porous alumina having a regular pore arrangement as a mask. The method of forming a similar structure in a polymer using the hollow array formed in this way as a template can be easily analogized, but in this method, it is difficult to form a tapered shape that is essential for the formation of a non-reflective layer. there were.

  In addition to these, a method of etching a porous structure of anodized porous alumina and producing a stamper based on this is proposed (for example, Patent Document 1). Since it is cylindrical, it is difficult to form a protrusion shape having a controlled taper shape necessary for the antireflection film on the polymer film simply based on this.

JP 2003-43203 A

Kanamori et al., Appl. Phys. Lett., Vol. 78, No. 2, p. 142 (2001)

  As described above, in the method using lithography, it is difficult to inexpensively manufacture a stamper capable of processing a large area, and it is difficult to control the taper shape. Also, the method using anodized porous alumina has a problem that it is difficult to form an optimum tapered shape essential for forming a non-reflective layer.

  Accordingly, an object of the present invention is to provide a casting mold made of anodized porous alumina capable of efficiently forming a desired antireflection film on the surface of a polymer film and a method for manufacturing the same, in order to solve the above-described problems in the prior art. There is.

In order to solve the above-mentioned problems, the present invention provides a non-reflective polymer by using anodized porous alumina having a tapered shape with continuously changing pore diameter as a template by combining anodization and pore diameter expansion treatment. This makes it possible to produce a film. That is, the manufacturing method of the casting_mold | template which consists of anodized porous alumina of this invention has the following processes.
(1) A step of forming pores by anodizing the aluminum substrate.
(2) A step of subjecting the pores to a pore diameter expansion process.
(3) A step of anodizing again after the step (2).
(4) A step of alternately repeating the step (2) and the step (3).
In the step (4), it is preferable that the step is completed by a pore diameter expansion process.
The mold made of the anodized porous alumina of the present invention is produced by the production method of the present invention.
The method for producing an antireflection film according to the present invention is a method for producing an antireflection film that reduces reflection by forming irregularities on the surface of a polymer film and continuously changing the refractive index. For the formation, the surface has pores, and the pores are combined with anodization and pore diameter expansion treatment, and anodized porous alumina having a tapered shape in which the pore diameter continuously changes is used as a template, or the It consists of a method characterized by using a stamper produced using anodized porous alumina as a mold.

  In this method of manufacturing an antireflection film, the use of anodized porous alumina having a pore period of 50 nm to 300 nm and a pore depth of 100 nm or more as a template can realize a more optimal antireflection film.

  In addition, an anode having high pore arrangement regularity is obtained by using anodized porous alumina prepared by anodizing at a constant voltage for a long time, once removing the oxide film, and again anodizing under the same conditions. It becomes possible to use oxidized porous alumina as a mold.

  As the anodized porous alumina to be used, for example, anodized porous alumina prepared using an oxalic acid as an electrolytic solution at a conversion voltage of 30 V to 60 V can be used, and sulfuric acid is used as an electrolytic solution at an conversion voltage of 25 V to 30 V. The produced anodized porous alumina can also be used. By using such anodized porous alumina, it becomes possible to use a hollow array having higher regularity as a template.

  Further, in the production of anodized porous alumina, a fine depression can be formed on the aluminum surface prior to anodization, and this can be used as a pore generation point during anodization. Thereby, it becomes possible to set it as the casting_mold | template which has a hollow arrangement | sequence which has arbitrary arrangement | sequences.

  The antireflection film according to the present invention is manufactured by such a method, and has excellent antireflection performance due to surface irregularities formed in a desired shape. By forming this antireflection film on the surface of the light-transmitting polymer film, the antireflection performance targeted in various applications can be exhibited.

  The manufacturing method of a stamper for producing an antireflection film according to the present invention is the production of a stamper used for producing an antireflection film that reduces reflection by forming irregularities on the surface of a polymer film and continuously changing the refractive index. A method using anodized porous alumina having a pore on the surface, and having a tapered shape in which the pore diameter continuously changes by combining anodization and pore diameter expansion treatment as a mold. It consists of the method characterized by this.

  The stamper for producing an antireflection film according to the present invention is manufactured by such a method.

  According to the present invention, it is possible to form a mold based on anodized porous alumina whose taper shape is controlled more easily than conventional methods, and as a result, antireflection with reduced reflection in the visible light region. The layer and the manufacturing method thereof, as well as the stamper for forming the antireflection layer, and the manufacturing thereof can be realized.

It is a schematic sectional drawing which shows the example of the polymer non-reflective film in which the surface protrusion arrangement | sequence was formed. In this invention, it is a figure which shows the process in which the anodic oxidation porous alumina which has a taper-shaped pore is formed by combining an anodic oxidation and an etching. It is a figure which shows the formation process of the polymeric non-reflective film which has a protrusion shape using the anodized porous alumina which has a taper-shaped pore as a casting_mold | template. It is a figure which shows the formation process of the stamper which consists of a metal using the anodized porous alumina which has a taper-shaped pore as a casting_mold | template. It is a figure which shows the process of producing the anodic oxidation porous alumina which has a taper-shaped pore with a high regularity by once dissolving and removing an oxidation layer after anodizing and performing anodization again. It is a figure which shows the process of producing the anodic oxidation porous alumina which has the taper-shaped pore by which the pore arrangement | sequence was controlled by forming the hollow arrangement | sequence on the aluminum surface using the mold which has a regular projection arrangement | sequence, and performing anodization .

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows an example of the structure of an antireflection film (non-reflection film) made of a polymer formed in the present invention. Since the surface of the polymer film 1 has a tapered protrusion arrangement, that is, unevenness, the refractive index changes continuously, and the reflectance can be reduced.

  FIG. 2 shows a method for producing anodized porous alumina having a tapered shape in the present invention. The anodized porous alumina 3 is formed on the surface of the aluminum substrate 2, but the shape of the pores 4 of the anodized porous alumina 3 is cylindrical, and as it is, for forming a non-reflective film. Use as a mold is difficult. In the present invention, anodized porous alumina having a desired taper-shaped hole is realized by combining anodization and hole enlargement processing by etching. After anodizing for a predetermined time to form pores having a desired depth, the pores are enlarged by being immersed in an appropriate acid solution. Thereafter, anodization is performed again to form a hole having a smaller hole diameter compared to the first stage. By repeating this operation, anodized porous alumina having a tapered shape can be obtained. At this time, a smoother taper shape can be obtained by increasing the number of steps. By adjusting the anodizing time and the hole diameter expansion processing time, it is possible to form holes with various taper shapes, and it is possible to design an optimal refractive index change according to the period and hole depth Become.

  As shown in FIG. 3, the structure is transferred to the polymer film (polymer film) 1 as shown in FIG. 3 (for example, the polymer is filled into the mold). The non-reflective structure having protrusions on the surface can be obtained by removing the template. As the polymer film 1, a film having good light transmittance and processability can be used, and representative examples include acrylic resin, polycarbonate resin, polystyrene resin and the like. For transfer to polymer, polymer film filled with monomer, polymer film dissolved in an appropriate solvent, cast polymer, heated or polymerized polymer film by adding solvent This can be achieved by pressing the mold into the mold.

  When anodized porous alumina having a tapered hole is used as a template, in addition to the method of directly using anodized porous alumina, as shown in FIG. It is also possible to obtain a new mold having an anti-reflection film, that is, a stamper for producing an antireflection film, which is effective for improving durability, wear resistance, or peeling characteristics. In the example shown in FIG. 4, first, the structure is transferred to the polymer 1 as a negative mold material using the anodized porous alumina 3 as a mold, and then the anodized porous alumina 3 is removed. Fill and remove the negative mold to obtain a stamper made of metal or the like.

  In the present invention, as shown in FIG. 5, prior to forming the tapered holes, anodization is performed for a relatively long time in advance to regularize the hole arrangement of the anodized porous alumina layer. By removing the alumina layer, a regular array of depressions corresponding to the bottom of the porous alumina (called the barrier layer) is obtained on the aluminum surface, and again by combining anodization at the same voltage and pore size expansion treatment, Tapered porous alumina in which pores are regularly arranged from the outermost surface is formed. That is, the reanodized layer 6 in which tapered pores having a preferable shape are arranged with higher regularity is formed. In general, in anodized porous alumina, the regularity of the pore arrangement of the outermost surface portion formed at the initial stage of anodization is low, and the light-reflective film formed based on such anodized porous alumina does not scatter light. Although it may be difficult to use as a good non-reflective film, it becomes possible to obtain anodized porous alumina with pores arranged with high regularity based on the above method, and good non-reflective film Contributes to film formation. At this time, when oxalic acid is used as the electrolytic solution, a high voltage is formed at a conversion voltage of 30 to 60 V, more preferably at 40 V, and when sulfuric acid is used as the electrolytic solution, a high voltage is formed at a conversion voltage of 25 to 30 V. It is known that anodized porous alumina having properties can be obtained (for example, Masuda, Applied Physics, vol. 69, No. 5, p. 558 (2000)). The anodized porous alumina having a highly ordered hole array formed in this way can be used directly or more effectively for the production of a metal mold or the like.

  Further, in the present invention, as shown in FIG. 6, a mold 7 having projections in a desired arrangement is used to form a depression array on the surface of the aluminum 2, and thereafter an anode with a conversion voltage suitable for the depression spacing. By combining the oxidation and the hole diameter enlargement process, it becomes possible to obtain anodized porous alumina having a tapered hole having a hole arrangement corresponding to the protrusion arrangement of the mold. According to this method, anodized porous alumina having an arbitrary period and arrangement can be formed, which contributes to obtaining a good antireflection film. This method not only obtains porous alumina having a highly regular pore array, but also contributes to suppression of the generation of interference colors due to light interference, which is a problem when used as a display material. The anodized porous alumina having a highly ordered hole array formed in this way can be used directly or more effectively for the production of a metal mold or the like.

Next, based on an Example, this invention is demonstrated further more concretely.
Example 1
An aluminum plate having a purity of 99.99% was subjected to anodization for 50 seconds with 0.3M oxalic acid as an electrolytic solution and a formation voltage of 40V. Then, it was immersed in 2% by weight phosphoric acid at 30 ° C. for 5 minutes and subjected to a pore size expansion treatment. By repeating this operation five times, an anodized porous alumina having tapered pores having a period of 100 nm, a pore diameter opening portion of 80 nm, a bottom portion of 25 nm, and a pore depth of 300 nm was obtained.

  A methyl methacrylate monomer containing 5% by weight of benzoyl peroxide as a polymerization initiator was filled in the pores, and then polymerized by irradiation with ultraviolet rays. After the polymerization, the polymer layer was peeled from the mold to obtain a polymethyl methacrylate resin having a protrusion arrangement on the surface. As a result of measuring the reflectance of the obtained polymer film, it was confirmed that the reflectance was reduced.

Example 2
With respect to the same aluminum plate as in Example 1, 0.3M sulfuric acid was used as the electrolytic solution, the formation voltage was 25V, and the anodic oxidation and the pore diameter expansion treatment were repeated. Thereafter, the structure was transferred to a polymethyl methacrylate resin in the same manner, thereby confirming a reduction in reflectance.

Example 3
After anodizing for 2 hours under the same conditions as in Example 1, the porous alumina layer was selectively dissolved and removed with a phosphoric acid / chromic acid mixture. Thereafter, anodized porous alumina having tapered pores with highly arranged pores was obtained by combining anodization and pore diameter expansion treatment under the same conditions. Thereafter, the structure was transferred to a polymethyl methacrylate resin by the same method as in Example 1, and it was confirmed that the reflectance was reduced.

Example 4
After forming anodized porous alumina having tapered holes by the same method as in Example 1, it was confirmed that low-reflectivity characteristics were exhibited by performing transfer to a polycarbonate resin using this as a template.

Example 5
After anodized porous alumina having tapered holes was formed by the same method as in Example 1, the anodized porous alumina was filled with polymethyl methacrylate to obtain a negative mold of porous alumina. Thereafter, the polymethyl methacrylate surface was subjected to a conductive treatment, and nickel was filled by a plating method. By dissolving and removing the polymethacrylate negative mold, a nickel positive mold having the same structure as the base anodized porous alumina was obtained. This was pressed against heated polymethylmethacrylate to obtain a low reflection film having a protrusion arrangement on the surface.

Example 6
By pressing a mold having a protrusion arrangement with a period of 200 nm against an aluminum plate, a depression array corresponding to the protrusion was obtained on the aluminum surface. Subsequently, 0.05M oxalic acid was used, and anodization at a conversion voltage of 80 V and pore diameter enlargement treatment were repeated five times, so that tapered pores having a period of 200 nm, a pore diameter opening portion of 160 nm, a bottom portion of 50 nm, and a pore depth of 500 nm were obtained. An anodized porous alumina having Thereafter, the structure was transferred to a polymethyl methacrylate resin in the same manner as in Example 1, and it was confirmed that the reflectance was reduced.

  The present invention can be applied to any application that requires the formation of an antireflection film, and is particularly suitable for display devices for various information devices that require improved visibility.

1 Polymer film (polymer film, polymer)
2 Aluminum 3 Anodized porous alumina 4 Pore 5 Metal (stamper)
6 Re-anodized layer 7 Mold

Claims (6)

The manufacturing method of the casting_mold | template which consists of an anodized porous alumina which has the following process.
(1) A step of forming pores by anodizing the aluminum substrate.
(2) A step of subjecting the pores to a pore diameter expansion process.
(3) A step of anodizing again after the step (2).
(4) A step of alternately repeating the step (2) and the step (3).   In the said process (4), the manufacturing process of the casting_mold | template which consists of an anodized porous alumina of Claim 1 which this process complete | finishes by a hole diameter expansion process.   The manufacturing method of the casting_mold | template consisting of the anodic oxidation porous alumina of Claim 1 or 2 which uses an oxalic acid as electrolyte solution, and anodizes with the formation voltage 30V-60V.   The manufacturing method of the casting_mold | template which consists of anodized porous alumina of Claim 1 or 2 which uses sulfuric acid as electrolyte solution and performs anodizing with the formation voltage of 25V-30V.   The casting_mold | template which consists of an anodized porous alumina manufactured by the method in any one of Claims 1-4.   The mold made of anodized porous alumina according to claim 5, which has a pore cycle of 50 nm to 300 nm and a pore depth of 100 nm or more.

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