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CN101071183A - Corrugated pattern forming sheet and method for manufacturing the same, and method for manufacturing antireflector, retardation plate, original process sheet plate, and optical element - Google Patents

Corrugated pattern forming sheet and method for manufacturing the same, and method for manufacturing antireflector, retardation plate, original process sheet plate, and optical element Download PDF

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Publication number
CN101071183A
CN101071183A CNA2007101017616A CN200710101761A CN101071183A CN 101071183 A CN101071183 A CN 101071183A CN A2007101017616 A CNA2007101017616 A CN A2007101017616A CN 200710101761 A CN200710101761 A CN 200710101761A CN 101071183 A CN101071183 A CN 101071183A
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China
Prior art keywords
sheet
concaveconvex shape
master
forms
hard layer
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Chinese (zh)
Inventor
冈安俊树
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New Oji Paper Co Ltd
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Oji Paper Co Ltd
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Abstract

A corrugated pattern forming sheet exhibiting excellent performance when being used as optical elements, such as an antireflector and a retardation plate is provided. A corrugated pattern forming sheet of the invention includes a resin layer, and a hard layer provided at least in a portion of an outer surface of the resin layer. The hard layer is made of a metal or a metallic compound. The hard layer has a wavelike corrugated pattern. The average pitch of the corrugated pattern is 1 mum or less, and the average depth of the bottom of the corrugated pattern is 10% or more given an average pitch of 100%.

Description

Concaveconvex shape forms the manufacture method of sheet and manufacture method, antireflection object, polarizer, operation sheet master and optical element
Technical field
The present invention relates to the concaveconvex shapes that optical element possessed such as antireflection object, polarizer and form sheet and manufacture method thereof.Also relate to the antireflection object, the polarizer that use concaveconvex shape to form sheet.Also relate to operation sheet master, as the mould of making the sheet that is formed with concaveconvex shape.The manufacture method that further relates to optical element.
Background technology
As optical elements such as antireflection object, polarizers, the known concaveconvex shape that can utilize forms sheet, the surface that forms sheet at this concaveconvex shape forms by the fine wavy concavo-convex concaveconvex shape of forming, and the average headway of concaveconvex shape is visual light wavelength following (with reference to a non-patent literature 1).
Here, average headway is meant, when concaveconvex shape during only along a direction, from the top of certain protuberance of concaveconvex shape at interval the mean value of spacing the top of the adjacent protuberance of this protuberance.And, obtain average headway in the following manner when concaveconvex shape during not along specific direction.At first, with atomic force microscope take concaveconvex shape above, be gray scale file (for example, tiff form etc.) with this image transformation.In the image (with reference to figure 4) of gray scale file, the part that whiteness is low more, the bottom dark more (part that whiteness is high more, the top of protuberance is high more) of expression recess.Then, the image to the gray scale file carries out Fourier transform.Figure 5 shows that the image behind the Fourier transform.In the image behind Fourier transform, the directivity of the direction indication gray scale of seeing from the center of white portion, and the inverse of the distance from the center to the white portion is represented the cycle of gray level image.Concaveconvex shape becomes the image that demonstrates white annulus as shown in Figure 5 during not along specific direction.Then, the boost line L of linearity is marked at the center of the annulus the image behind Fourier transform laterally 2, and corresponding brightness (Y-axis) curve (with reference to figure 6) of distance (X-axis) that draws and begin from the center.Then, read in the value r of the X-axis of expression maximum value in this curve.The inverse of this r (1/r) is an average headway.
It is because following reason that concaveconvex shape formation sheet can be used as the antireflection object utilization.
When the surface of sheet is not provided with concaveconvex shape,, the refractive index in the interface between sheet and the air produces reflection owing to sharply changing.But, the surface of sheet promptly and air between the wavy concaveconvex shape of layout setting the time, value between the refractive index that refractive index in the concaveconvex shape part is expressed as air and the refractive index of concaveconvex shape formation sheet (below, be called middle refractive index), and this middle refractive index changes on the depth direction of concaveconvex shape continuously.Particularly, in dark more position, form the refractive index of sheet more near concaveconvex shape.When middle refractive index changed continuously in such a way, rapid variation can not take place in the refractive index in the aforesaid interface, can suppress reflection of light.And, if the spacing of concaveconvex shape is below the visual light wavelength, then concaveconvex shape partly be difficult for causing by visual diffraction of light be visual interference of light cause painted.
In addition, concaveconvex shape forms sheet to can be used as the polarizer utilization is because when the different mutually air of the part alternate configurations refractive index of concaveconvex shape and concaveconvex shape formed sheet, its result was to shining the light performance optical anisotropy of concaveconvex shape side.And, the spacing of concaveconvex shape and visual light wavelength in same range as or the spacing of concaveconvex shape be visual light wavelength when following, the phenomenon of expression equal phase difference appears in wide wavelengths of visible light zone.
Form the concrete example of sheet as this concaveconvex shape, for example, non-patent literature 2 has proposed the sheet that obtains by the following method, cooling after an evaporation metal of the sheet that the dimethyl silicone polymer of heating is formed forms metal level, the sheet that dimethyl silicone polymer is formed shrinks, thereby forms wavy concaveconvex shape on the surface of metal level.
In addition, patent documentation 1 has proposed following sheet, on the surface of heat-shrinkable synthetic resin film, forms successively after substrate layer and the metal level, makes the thermal shrinkage of heat-shrinkable synthetic resin film, thereby forms the sheet of wavy concaveconvex shape on the surface of metal level.
Patent documentation 2 has proposed following sheet, forms the layer by the material formation of exposure-processed volumetric contraction, this layer is carried out exposure-processed, thereby form concavo-convex sheet on the surface.
But the concaveconvex shape of record forms sheet in patent documentation 1,2 and the non-patent literature 2, does not all demonstrate excellent performance as optical element.Particularly, when using, can't fully reduce reflectivity, and when using, can't fully enlarge phase differential, and can't produce the phase differential that equates in wide wavelength region may as polarizer as antireflection object.
In addition, as making the method that concaveconvex shape forms sheet, the known photoetching process (photolithography) that the visible light of use pattern mask (patternmask) is arranged.But this method can not be made the concaveconvex shape with the following spacing of light wavelength that can be used as the optical element utilization and form sheet.Therefore, need to use more ultraviolet laser interferometric method, the electron beam exposure method (lithography) of microfabrication.In these methods, expose with ultraviolet laser interference light, electron beam and develop being formed on resist (resist) layer on the substrate, form the resist graph layer, and with this resist graph layer as mask, form concaveconvex shape by dry etching method etc.But, when using ultraviolet laser interferometric method, electron beam exposure method, have following problem: be difficult to be not suitable for a large amount of productions surpassing the wide zone processing of 10cm.
In addition, patent documentation 3 has proposed to dispose particle layer on substrate, particle layer is carried out the method for dry etching to substrate surface as etching mask.But also there is following problem in this method: be difficult to be not suitable for a large amount of productions surpassing the wide zone processing of 30cm.
Patent documentation 1: the spy opens clear 63-301988 communique
Patent documentation 2; The spy opens the 2003-187503 communique
Patent documentation 3: the spy opens the 2005-279807 communique
Non-patent literature 1: chrysanthemum Tian Jiuxiong, rock Tagayasu Den one work, " optics ", and Japanese optics can be issued, the 27th volume, and No. 1,1998, p.12-17
Work such as non-patent literature 2:Ned Bowden, " nature (nature) ", No. 393,1998, p.146
Summary of the invention
In view of this, the object of the present invention is to provide a kind of concaveconvex shape of time performance excellent properties that utilizes as optical elements such as antireflection object, polarizers to form sheet.In addition, the object of the present invention is to provide a kind of concaveconvex shape to form the manufacture method of sheet, can make this concaveconvex shape easy, in large area and form sheet.In addition, the object of the present invention is to provide the low antireflection object of a kind of reflectivity, a kind of polarizer that produces the equal phase difference in wide wavelength region may is provided.In addition, the object of the present invention is to provide a kind of operation sheet master, can be easy and a large amount of manufacturings form the sheet of the concaveconvex shape that is suitable as optical element.Further, the object of the present invention is to provide a kind of manufacture method of optical element, can make optical element easy and in a large number, form on this optical element and be suitable as the average headway of optical element and the concaveconvex shape of mean depth.
The result that the present inventor studies the performance that improves optical elements such as antireflection object, polarizer has invented following concaveconvex shape and has formed sheet.And, studied the manufacture method that is used to make this concaveconvex shape formation sheet, invented the manufacture method that following concaveconvex shape forms sheet.And, the manufacture method of having invented following antireflection object, polarizer, operation sheet master and optical element.
(1) a kind of concaveconvex shape forms sheet, comprises the hard layer of resin bed and at least a portion that is arranged on this resin bed outside, forms wavy concaveconvex shape at this hard layer, it is characterized in that the matter layer is made up of metal or metallic compound;
The average headway of concaveconvex shape is that the mean depth of the bottom of concaveconvex shape is for to be used as described average headway as 100% o'clock more than 10% below the 1 μ m.
(2) form sheet according to (1) described concaveconvex shape, wherein, hard layer is made up of metallic compound.
(3) form sheet according to (2) described concaveconvex shape, wherein, metallic compound is, at least a kind of metallic compound selecting among the group who forms from titanium dioxide, aluminium oxide, zinc paste, magnesium oxide, tin oxide, cupric oxide, indium oxide, cadmium oxide, massicot, monox, barium fluoride, calcium fluoride, magnesium fluoride, zinc sulphide, gallium arsenide.
(4) form sheet according to (1) described concaveconvex shape, wherein, hard layer is made up of metal.
(5) form sheet according to (4) described concaveconvex shape, wherein, metal is, at least a kind of metal of selection among the group who forms from gold, aluminium, silver, carbon, copper, germanium, indium, magnesium, niobium, palladium, lead, platinum, silicon, tin, titanium, vanadium, zinc, bismuth.
(6) a kind of concaveconvex shape forms the manufacture method of sheet, it is characterized in that this method comprises following operation:
At least a portion in the resin bed outside is provided with the hard layer of surface smoothing, the operation of cambium layer compressing tablet; At least make the crawl operation of distortion of the hard layer of this laminate;
Wherein, hard layer constitutes with metal or metallic compound.
(7) a kind of antireflection object, wherein, wantonly 1 described concaveconvex shape that this antireflection object has in (1)~(5) forms sheet.
(8) a kind of polarizer, wherein, wantonly 1 described concaveconvex shape that this polarizer has in (1)~(5) forms sheet.
(9) wantonly 1 described concaveconvex shape that a kind of operation sheet master, this operation sheet master have in (1)~(5) forms sheet; This operation sheet master uses as mould, and this mould is used to make the sheet of the concaveconvex shape that forms the average headway that equates with this concaveconvex shape formation sheet and mean depth.
(10) a kind of manufacture method of optical element, this method comprises following operation:
In (9) described operation sheet master, form the face of concaveconvex shape, be coated with the operation of unhardened hardening resin;
After making this hardening resin sclerosis, from the operation of filming of operation sheet master strip hardened.
(11) a kind of manufacture method of optical element, this method comprises following operation:
In (9) described operation sheet master, form the face of concaveconvex shape, the operation of contact sheet thermoplastic resin;
When this thermoplastic resin is pressed in operation sheet master, after heating makes it softening, the operation of cooling off;
Peel off the operation of the sheet thermoplastic resin of cooling from operation sheet master.
(12) a kind of manufacture method of optical element, this method comprises following operation:
In (9) described operation sheet master, form the face of concaveconvex shape, the lamination concaveconvex shape transfer printing operation of material;
From the peeling laminated concaveconvex shape transfer printing material of described operation sheet master, make the operation of 2 operation sheets at concaveconvex shape;
The face of the side of joining with the concaveconvex shape of described operation sheet master in these 2 operation sheets is coated with the operation of unhardened hardening resin;
After making this hardening resin sclerosis, from the operation of filming of 2 operation sheet strip hardened.
(13) a kind of manufacture method of optical element, this method comprises following operation:
In (9) described operation sheet master, form the face of concaveconvex shape, the lamination concaveconvex shape transfer printing operation of material;
From the peeling laminated concaveconvex shape transfer printing material of described operation sheet master, make the operation of 2 operation sheets at concaveconvex shape;
The face of the side of in these 2 operation sheets, joining with the concaveconvex shape of described operation sheet master, the operation of contact sheet thermoplastic resin;
When this thermoplastic resin is pressed in 2 operation sheets, after heating makes it softening, the operation of cooling off;
Peel off the operation of the sheet thermoplastic resin of cooling from 2 operation sheets.
Concaveconvex shape of the present invention forms sheet, can be suitable as optical element utilizations such as antireflection object, polarizer.In addition, concaveconvex shape of the present invention forms sheet, also can be suitable as the utilization of operation sheet master, and this operation sheet master uses as the mould of making the sheet that forms wavy concaveconvex shape.
Form in the manufacture method of sheet at concaveconvex shape of the present invention, owing to can easily form fine concaveconvex shape, form sheet so can make the concaveconvex shape that is fit to be used in optical element etc. easy, in large area in surperficial large tracts of land.
Antireflection object of the present invention, reflectivity is low, excellent performance.
Polarizer of the present invention can produce the phase differential that equates, excellent performance in wide wavelength region may.
The operation sheet master of the application of the invention can be easy and make the sheet of the concaveconvex shape that forms the average headway that is suitable as optical element and mean depth in large quantities.
According to the manufacture method of optical element of the present invention, can be easy and make the optical element of the concaveconvex shape that forms the average headway that is suitable as optical element and mean depth in large quantities.
Description of drawings
The amplification oblique drawing of Fig. 1 part of an embodiment of concaveconvex shape formation sheet of the present invention for amplification shows.
Fig. 2 is the sectional drawing the when concaveconvex shape of Fig. 1 is formed the orthogonal directions cut-out of formation direction that sheet press concaveconvex shape.
Figure 3 shows that concaveconvex shape of the present invention forms the sectional drawing of the laminate in the embodiment of manufacture method of sheet.
Fig. 4 is the grey scale change image of the surperficial resulting image when taking concaveconvex shape not along specific direction with atomic force microscope.
Fig. 5 is for carrying out the image of Fourier transform to the image of Fig. 4.
The corresponding brightness curve figure of distance that Fig. 6 begins for the circle ring center from the image of Fig. 5.
Fig. 7 forms the method one routine key diagram that sheet is made optical element for using concaveconvex shape of the present invention.
The explanation of symbol
10 concaveconvex shapes form sheet 10a laminate
11 resin beds, 12 hard layers
12a concaveconvex shape 12b bottom
The hard layer of 13 surface smoothings (surface smoothing hard layer)
Embodiment
(concaveconvex shape formation sheet)
An embodiment that concaveconvex shape of the present invention is formed sheet describes.
The concaveconvex shape that Figure 1 shows that present embodiment forms sheet.The concaveconvex shape of present embodiment forms the whole hard layer 12 of one side that sheet 10 comprises resin bed 11 and is arranged on resin bed 11; Hard layer 12 has the wavy concaveconvex shape 12a of periodicity that forms the Width of sheet 10 along this concaveconvex shape.
Resin bed 11 for example is made of silicone resins such as polystyrene resins such as polyolefin such as polyester such as polyethylene terephthalate, tygon or polypropylene, styrene-butadiene block copolymer, Polyvinylchloride, polyvinylidene chloride, dimethyl silicone polymer, fluororesin, ABS resin, polyamide, acryl resin, polycarbonate, poly-cycloolefin resins such as (poly cycloolefin).
The thickness of resin bed 11 is preferably 0.3~500 μ m.If the thickness of resin bed 11 is more than the 0.3 μ m, then concaveconvex shape forms not cracky of sheet 10, if thickness is below the 500 μ m, then the slimming concaveconvex shape forms sheet 10 easily.In addition, in order to support resin bed 11, the resinous base material of thickness 5~500 μ m can be set.
Hard layer 12 is made up of metal or metallic compound.
Consider that Young modulus is within reason and increase, more easily form the reason of concaveconvex shape 12a, as metal, preferably among the group who forms by gold, aluminium, silver, carbon, copper, germanium, indium, magnesium, niobium, palladium, lead, platinum, silicon, tin, titanium, vanadium, zinc, bismuth, select at least a kind of metal.Here said metal also comprises semimetals such as carbon, germanium, tin.
For the same reason, as metallic compound, preferably among the group who forms by titanium dioxide, aluminium oxide, zinc paste, magnesium oxide, tin oxide, cupric oxide, indium oxide, cadmium oxide, massicot, monox, barium fluoride, calcium fluoride, magnesium fluoride, zinc sulphide, gallium arsenide, select at least a kind of metallic compound.Wherein, titanium dioxide is to be irradiated to the organic photocatalyst of light time decomposition attached to the surface, has self-cleaning function, so preferable.
In addition, when hard layer 12 was made up of metal, laminar surface can oxidation by air form the air oxidation film, but in the present invention, with the layer of such layer on surface of metal oxidation by air, equally also be considered as by metal forms layer.
The thickness of hard layer 12 is preferably 1~30nm.If the thickness of hard layer 12 is more than the 1nm, then hard layer 12 is difficult for producing defective, if thickness is below the 30nm, then hard layer 12 can fully be guaranteed photopermeability.
In addition, the thickness of hard layer 12 more is preferably below the 10nm, especially is preferably below the 5nm.If the thickness of hard layer 12 is below the 10nm, then can easily makes concaveconvex shape as hereinafter described and form sheet.
Also having, is purpose to improve cohesive, to form finer structure, between resin bed 11 and hard layer 12, also can form bottom (primer).
And, on hard layer 12, also resin bed can be set.
The average headway A that concaveconvex shape forms the concaveconvex shape 12a of sheet 10 is below the 1 μ m, is preferably below the 0.7 μ m, more is preferably below the 0.4 μ m.And consideration can form this point of concaveconvex shape 12a easily, and average headway A is preferably more than the 0.05 μ m.
Here, average headway A is each spacing A 1, A 2, A 3Mean value.
In addition, if concaveconvex shape to the expansion of direction, but when two-dimensional directional is expanded, carries out the method for Fourier transform and obtains average headway by the image to concaveconvex shape.Specifically ask method as follows.
At first, the image transformation above the concaveconvex shape that will take with atomic force microscope is the gray scale file, and the image (with reference to figure 4) of this document is carried out Fourier transform, obtains the image (with reference to figure 5) of white annulus.Then, corresponding brightness (Y-axis) curve (with reference to figure 6) of distance (X-axis) that begins from circle ring center that draws and see in the image behind Fourier transform.Then, read the value r of the X-axis of expression maximum value in this curve, the inverse of this r (1/r) is an average headway.
Average headway A is used as at 100% o'clock, and the mean depth B of the bottom 12b of concaveconvex shape 12a is more than 10%, is preferably more than 30%, more is preferably more than 100%.And consideration can form this point of concaveconvex shape 12a easily, and mean depth B is preferably average headway A is used as 100% o'clock below 500%.
Here, bottom 12b is meant the flex point of the recess of concaveconvex shape 12a, and mean depth B is, when observing the section (with reference to figure 2) that cuts off concaveconvex shape formation sheet 10 along its length, with the parallel datum line L of direction of 10 whole of concaveconvex shape formation sheets 1Arrive the length B at the top of each protuberance 1, B 2, B 3Mean value (B Av), with, datum line L 1Arrive the length b of the bottom of each recess 1, b 2, b 3Mean value (b Av) between poor (b Av-B Av).
The top of described protuberance and the bottom of described recess are meant, the part of the opposite sides of resin bed 11 sides in hard layer 12.
The result of present inventor's research shows, the average headway A of concaveconvex shape 12a is below the 1 μ m, especially be below the 0.4 μ m, the mean depth B of the bottom 12b of concaveconvex shape 12a is for to be used as average headway A as 100% o'clock more than 10%, especially be 100% when above, can bring into play excellent performance as optical element.Particularly, when concaveconvex shape is formed sheet 10 and uses as antireflection object, can reduce reflectivity, and when using, can produce the phase differential that equates in wide wavelength region may as polarizer.
This is because not only the average headway A of concaveconvex shape 12a is as short as below the 1 μ m, and mean depth B is deep to average headway A is used as 100% o'clock more than 10%.In other words, average headway A is short, and is identical with visual light wavelength or be below it, and like this, because concavo-convex, visible light is difficult for generation diffraction, scattering.On this basis, mean depth B is dark, and like this, middle refractive index continually varying part prolongs on thickness direction, so, can bring into play the effect that suppresses reflection of light significantly.Also have, average headway A is short, mean depth B is dark, and like this, the part that mutually different air of refractive index and concaveconvex shape form the sheet alternate configurations prolongs on thickness direction, and it is elongated to show optically anisotropic part, therefore can produce phase differential.And this phase differential that produces according to concaveconvex shape 12a equates in wide wavelength region may part omitted.
Each spacing A of concaveconvex shape 12a 1, A 2, A 3All preferably average headway A ± 60% scope in, more preferably in ± 30% scope.If each spacing average headway A ± 60% scope in, then spacing is even, as the more excellent performance of optical element performance.
Also has each spacing A 1, A 2, A 3Under the average headway A that satisfies these spacings is situation below the 1 μ m, also can change continuously.
Each depth B of concaveconvex shape 12a 1, B 2, B 3All preferably mean depth B ± 60% scope in, more preferably in ± 30% scope.If each degree of depth mean depth B ± 60% scope in, then the degree of depth is even, as the more excellent performance of optical element performance.
Also has each depth B 1, B 2, B 3At the mean depth B that satisfies these degree of depth average headway A is being used as under 100% o'clock the situation more than 10%, also can changing continuously.
As described in follow-up, concaveconvex shape of the present invention forms sheet 10 except being applied to optical elements such as antireflection object, polarizer, optical element manufacturing with the operation sheet, can also be used in super-hydrophobic or super hydrophilic sheet.
In addition, concaveconvex shape of the present invention forms sheet and is not limited to above-mentioned embodiment.For example, in the above-mentioned embodiment, form the wavy concaveconvex shape of periodicity that forms the Width of sheet along this concaveconvex shape at hard layer, but except this concaveconvex shape, also can have the wavy concaveconvex shape of periodicity that forms the length direction of sheet along concaveconvex shape.Even, also can form a lot not along the wavy concaveconvex shape of specific direction at hard layer.In these cases, the average headway of concaveconvex shape is below the 1 μ m, and the mean depth of the bottom of concaveconvex shape like this, also can show excellent performance as optical element for described average headway is used as 100% o'clock more than 10%.
The shape of protuberance is considered this point of refractive index, and it is precipitous to be preferably front end, but front end also can have circle.
When hard layer forms not wavy concaveconvex shape along specific direction, the method that can adopt as the method for measuring its mean depth is, according to the degree of depth of each bottom of image measurement of the section of the concaveconvex shape of taking with atomic force microscope, and obtain these methods such as mean value.
(concaveconvex shape forms the manufacture method of sheet)
The embodiment that concaveconvex shape of the present invention is formed the manufacture method of sheet describes below.
As shown in Figure 3, the manufacture method that the concaveconvex shape of present embodiment forms sheet comprises following operation: the operation that hard layer 13 (below, be called surface smoothing hard layer 13) the cambium layer compressing tablet 10a of surface smoothing all is set in the one side of resin bed 11; The operation that in laminate 10a, makes surface smoothing hard layer 13 crawl and be out of shape at least.
Here, surface smoothing hard layer 13 is meant that the center line average boldness of putting down in writing among the JIS B0601 is the following layer of 0.1 μ m.
In this method, constitute surface smoothing hard layer 13 with metal or metallic compound.Owing to constitute surface smoothing hard layer 13 with metal or metallic compound, like this, when making resin bed 11 distortion, surface smoothing hard layer 13 warpages are wavy, make its distortion of crawling, thereby can easily form concaveconvex shape 12a.
As this manufacture method, for example, can use following method (1)~(5).
(1) at whole surface smoothing hard layers 13 that are provided with of the one side of resin bed 11, cambium layer compressing tablet 10a is with the whole method that direction is compressed along the surface of laminate 10a.
(2) at whole surface smoothing hard layers 13 that are provided with by the one side of the resin bed of forming to the shrink film of an axle or two direction of principal axis thermal shrinkages 11, cambium layer compressing tablet 10a, and, the surface smoothing hard layer 13 of resin bed 11 direction or two methods of compressing more than the direction along the surface will be laminated to by making resin bed 11 thermal shrinkages.
(3) at whole surface smoothing hard layers 13 that are provided with of the one side of resin bed 11, cambium layer compressing tablet 10a, laminate 10a is extended to a direction, make it in the direction contraction of bearing of trend quadrature relatively, thereby with the method that direction compress of surface smoothing hard layer 13 along the surface.
(4) the level and smooth hard layer 13 of resin bed 11 laminating surfaces that is forming by unhardened ionizing radiation hardening resin, cambium layer compressing tablet 10a, by irradiation ionizing radiation hard resin-layer 11 it is shunk, the method that the surface smoothing hard layer 13 that is laminated to resin bed 11 is compressed along at least one direction on surface.
(5) utilizing on the swollen resin layer 11 of solvent swelling, the level and smooth hard layer 13 of laminating surface, cambium layer compressing tablet 10a, by solvent dry and that remove in the resin bed 11 resin bed 11 is shunk, the method that the surface smoothing hard layer 13 that is laminated to resin bed 11 is compressed along at least one direction on surface.
In the method (1),, for example, can be set forth in an evaporation metal of resin bed 11, the method for metallic compound, method of the surface smoothing hard layer of making in advance at a lamination of resin bed 11 13 etc. as the method for cambium layer compressing tablet 10a.
In this manufacture method, in order more easily to form concaveconvex shape 12a, preferably the Young modulus with surface smoothing hard layer 13 is made as 0.1~500GPa, more preferably is made as 1~150GPa.
For the Young modulus with surface smoothing hard layer 13 is made as aforementioned range, surface smoothing hard layer 13 preferably selects at least a kind of metal to constitute among the group who is made up of gold, aluminium, silver, carbon, copper, germanium, indium, magnesium, niobium, palladium, lead, platinum, silicon, tin, titanium, vanadium, zinc, bismuth.Perhaps, surface smoothing hard layer 13 preferably selects at least a kind of metallic compound to constitute among the group who is made up of titanium dioxide, aluminium oxide, zinc paste, magnesium oxide, tin oxide, cupric oxide, indium oxide, cadmium oxide, massicot, monox, barium fluoride, calcium fluoride, magnesium fluoride, zinc sulphide, gallium arsenide.
Here, the value of Young modulus for measuring after in JIS Z 2280-1993 " test method of metal material Young modulus under the high temperature ", temperature variation being 23 ℃.When hard layer is made up of metallic compound too.
The thickness of surface smoothing hard layer 13 is preferably below the 10nm, more is preferably below the 7nm, especially is preferably below the 5nm.If the thickness of surface smoothing hard layer 13 is below the 10nm, then can be reliably the average headway A of concaveconvex shape 12a be made below the 1 μ m.
And for the hard layer after compressing 12 is difficult for producing defective, surface smoothing hard layer 13 is preferably more than the 1nm.
Also have, the thickness of surface smoothing hard layer 13 also can change continuously.When the thickness of surface smoothing hard layer 13 changes continuously, the spacing A of the formed concaveconvex shape 12a in compression back 1, A 2, A 3And depth B 1, B 2, B 3Can change continuously.
As with the method that direction compress of whole laminate 10a, for example, can enumerate and clamp method of the end of the end of laminate 10a and its opposition side compressing etc. with vice etc. along the surface.
Laminate 10a when a direction is out of shape, is preferably made 13 distortion of surface smoothing hard layer with the deformation rate more than 5%, more preferably make 13 distortion of surface smoothing hard layer with the deformation rate more than 30%.If make surface smoothing hard layer 13 distortion, the mean depth B of the bottom 12b of concaveconvex shape 12a is become average headway A is used as 100% o'clock more than 10% with the deformation rate more than 5%.
And, more preferably make 13 distortion of surface smoothing hard layer with the deformation rate more than 50%.If make surface smoothing hard layer 13 distortion, the mean depth B of the bottom 12b of concaveconvex shape 12a is become average headway A is used as 100% o'clock more than 100% with the deformation rate more than 50%.
Here, deformation rate is: (length after the length-distortion before the distortion)/(length before the distortion) * 100 (%).Or: (length of distortion)/(length before the distortion) * 100 (%).
When two-dimensional directional was out of shape, the deformation rate of the direction that distortion is maximum preferably was made as more than 5%, more preferably is made as more than 50%.
In the method (2), as the shrink film that resin bed 11 uses, for example, can enumerate polyethylene terephthalate is shrink film, polystyrene shrink film, polyolefin shrink film, polyvinyl chloride shrink film etc.Among shrink film, preferable shrink film for contraction 50~70%.Use and shrink 50~70% shrink film, then can make above-mentioned deformation rate is more than 50%, and the average headway A that can easily make concaveconvex shape 12a is that 1 μ m is following, the mean depth B of the bottom 12b of concaveconvex shape 12a is used as average headway A 100% o'clock the concaveconvex shape formation sheet 10 more than 10%.And the mean depth B that also can easily make the bottom 12b of concaveconvex shape 12a is used as average headway A 100% o'clock the concaveconvex shape formation sheet 10 more than 100%.
Also can use stretched film to replace shrink film.
Heating means when making resin bed 11 thermal shrinkages can be enumerated by the method in hot blast, steam or the hot water, wherein, consider and can evenly shrink that preferred methods is the method by hot water.
Heating-up temperature when making resin bed 11 thermal shrinkages preferably according to the desired value of the depth B of the spacing A of the kind of employed shrink film and concaveconvex shape 12a and bottom 12b, is suitably selected.
Use forms wavy concaveconvex shape 12a along the direction of shrinkage direction quadrature relatively when the shrink film of a direction of principal axis thermal shrinkage.Use forms not the wavy concaveconvex shape along specific direction when the shrink film of two direction of principal axis thermal shrinkages.
Surface smoothing hard layer 13 in the method (2) can use and middle same metal and the metallic compound of surface smoothing hard layer that uses of method (1), can be made as the thickness same with it.In addition, with in the method (1) similarly, the formation method of laminate 10a can be applied in the method for the evaporation metal or the metallic compound of resin bed 11, the method for the surface smoothing hard layer of making in advance at a lamination of resin bed 11 13.
In the method (3),, for example, can enumerate method that the mode of the end of a end by drawing laminate 10a and its opposition side extends etc. as method to a direction extended layer compressing tablet 10a.
In the method (4), can enumerate uv-hardening resin, electron-beam curing type resin etc. as the ionizing radiation hardening resin.
In the method (5), according to the resin kind that constitutes resin bed 11 selective solvent suitably.The baking temperature of solvent is then suitably selected according to solvent types.
For the surface smoothing hard layer 13 in method (3)~(5), also can use and the middle same composition of surface smoothing hard layer that uses of method (1), can be made as the thickness same with it.And, with in the method (1) similarly, the formation method of laminate 10a can be applied in the method for the evaporation metal or the metallic compound of resin bed 11, the method for the surface smoothing hard layer of making in advance at a lamination of resin bed 11 13.
Concaveconvex shape in above explanation forms in the manufacture method of sheet, because the Young modulus of the surface smoothing hard layer of being made up of metal or metallic compound 13 differs very big than the Young modulus of resin bed 11, so, when comparative resin layer 11 hard surface smoothing hard layer 13 compress or shrink, comparing thickness increases, and can become folded state.And, because surface smoothing hard layer 13 is laminated on resin bed 11, so the stress in compression, the contraction process can put on integral body equably.Therefore, according to the present invention, the distortion of can easily crawling is made concaveconvex shape and is formed sheet 10.So the concaveconvex shape that can make easy and in large area as the optical element performance excellence forms sheet 10.
And, according to this manufacture method, the average headway A of concaveconvex shape 12a not only can be easily shortened, and mean depth B can be easily deepened.Particularly, can be easily the average headway A of concaveconvex shape 12a be made as below the 1 μ m, the mean depth B of the bottom 12b of concaveconvex shape 12a be made as average headway A is used as 100% o'clock more than 10%.
And, according to this manufacture method, can easily make each the spacing A among the concaveconvex shape 12a 1, A 2, A 3And each depth B 1, B 2, B 3Evenly.
Form the method for using sheet as making concaveconvex shape, at present known hot nano impression method and light nano impression method.Hot nano impression method is, the concaveconvex shape that will be used for the mould of nano impression is pressed in behind heating and the softening sheet thermoplastic resin its cooling; Light nano impression method is that after covering unhardened ionizing radiation hardening resin constituent on the concaveconvex shape of the mould that is used for nano impression, the irradiation ionizing radiation makes its sclerosis.
In hot nano impression method, need apply uniform pressure to mold integral, the mould that will be formed with concaveconvex shape is pressed in thermoplastic resin, but in this method, if the area of mould increases, then inhomogeneous easily to the mould applied pressure, its result causes the transfer printing of concaveconvex shape to become inhomogeneous.So this method and the employed large-area concave-convex shape such as display that is not suitable for LCD TV form the production of sheet.
And, in light nano impression method, because the demoulding fully between the resin of mould and sclerosis, so cause the transfer printing of concaveconvex shape to become incomplete.And along with the repeated use increased frequency of mould, this tendency is more and more obvious.
To this, above-mentioned concaveconvex shape forms the manufacture method of sheet owing to the transfer printing of having omitted concaveconvex shape, so can solve the problems referred to above in the nano impression method.
In addition, in the above-mentioned embodiment, one side at resin bed all is provided with the surface smoothing hard layer, but also can the surface smoothing hard layer be set in the part of the one side of resin bed, can also the surface smoothing hard layer all be set on the two sides of resin bed, also can the surface smoothing hard layer be set in the part on the two sides of resin bed.
(antireflection object)
Antireflection object of the present invention comprises that above-mentioned concaveconvex shape forms sheet 10.
In antireflection object of the present invention, form on the one side of sheet 10 or the two sides at concaveconvex shape and also can dispose other layer.For example, in forming sheet 10, concaveconvex shape is formed with on the face of side of concaveconvex shape 12a, and contaminated in order to prevent this face, can dispose that to contain with fluororesin or silicone resin be stain-proofing layer about the thickness 1~5nm of principal ingredient.
And, form the face that is not formed with the side of concaveconvex shape 12a in the sheet 10 at concaveconvex shape, for example can dispose base material.As base material, for example, can enumerate resinous of triacetyl cellulose etc.
Antireflection object of the present invention forms the part of the wavy concaveconvex shape 12a of sheet 10 at concaveconvex shape, show as the middle refractive index between the refractive index (refractive index of resin bed 11) that the refractive index of air and concaveconvex shape form sheet 10, this middle refractive index changes continuously.And the average headway A of concaveconvex shape 12a is below the 1 μ m, and the mean depth B of the bottom 12b of concaveconvex shape 12a is for to be used as average headway A as 100% o'clock more than 10%.Because these points can reduce the reflection of light rate significantly, particularly, reflectivity is almost 0%.This be because, as mentioned above, not only the average headway A of the concaveconvex shape 12a of concaveconvex shape formation sheet 10 is as short as below the 1 μ m, and mean depth B is deep to average headway A is used as 100% o'clock more than 10%, middle refractive index continually varying part prolongs on thickness direction, thereby can bring into play the effect that suppresses the light reflection significantly.
This antireflection object for example, can be installed on the illuminating part front end of image display devices such as LCD panel, plasma display, light emitting diode, the surface of solar panel etc.
When being installed on image display device, owing to the reflection that can prevent to throw light on, thus the visibility of raising image.When being installed on the illuminating part front end of light emitting diode, improve luminescence efficiency.When being installed on solar panel surperficial,, thereby improve the generating efficiency of solar cell because the intake of light increases.
(polarizer)
Polarizer of the present invention possesses above-mentioned concaveconvex shape and forms sheet 10.But concavo-convex direction is not at random, but along a direction.
In polarizer of the present invention, with above-mentioned antireflection object similarly, form on the one side of sheet 10 or the two sides at concaveconvex shape and also can dispose other layer, for example, on concaveconvex shape forms the face of the side that is formed with concaveconvex shape 12a in the sheet 10, can dispose stain-proofing layer.
And, form the face that is not formed with the side of concaveconvex shape 12a in the sheet 10 at concaveconvex shape, for example can dispose base material.As base material, for example, can enumerate resinous of triacetyl cellulose etc.
Also have,, can also further form concaveconvex shape in the opposite sides of the face that forms concaveconvex shape.
Polarizer of the present invention can be brought into play the effect that produces phase differential significantly.This be because, as mentioned above, not only the average headway A of the concaveconvex shape 12a of concaveconvex shape formation sheet 10 is as short as below the 1 μ m, and mean depth B is deep to average headway A is used as 100% o'clock more than 10%, thereby air that refractive index is different mutually and concaveconvex shape form the part of sheet 10 alternate configurations and prolong on thickness direction, and it is elongated to show optically anisotropic part.And, the spacing of concaveconvex shape identical with visual light wavelength or be its when following, can produce the phase differential that equates in wide wavelengths of visible light zone.
(operation sheet master)
Operation sheet master of the present invention possesses above-mentioned concaveconvex shape and forms sheet 10, use as a kind of mould, the method that illustrates below by usefulness is transferred to other material with concaveconvex shape, obtain to have the average headway that equates and the concaveconvex shape of mean depth with this operation sheet master, large tracts of land is also made the concaveconvex shape formation sheet that optical elements such as can be used as antireflection object, polarizer use in large quantities.
Operation sheet master may further include and is used to support that concaveconvex shape forms the resin system or the metal support of sheet 10.
As using operation sheet master to make the concrete grammar of optical element, for example, can enumerate following method (a)~(c).
(a) method comprises: form the face of concaveconvex shape in operation sheet master, be coated with the operation of unhardened ionizing radiation hardening resin; After the irradiation ionizing radiation makes described hardening resin sclerosis, from the operation of filming of operation sheet master strip hardened.Here, ionizing radiation typically refers to ultraviolet ray or electron beam, but the present invention also comprises visible rays, X ray, ion line etc.
(b) method comprises: form the face of concaveconvex shape in operation sheet master, be coated with the operation of unhardened aqueous thermosetting resin; After heating makes described aqueous thermosetting resin sclerosis, from the operation of filming of operation sheet master strip hardened.
(c) method comprises: form the face of concaveconvex shape in operation sheet master, the operation of the thermoplastic resin of contact sheet; When this thermoplastic resin is pressed in engineering sheet master, after heating makes it softening, the engineering of cooling off; Peel off the operation of the sheet thermoplastic resin of this cooling from operation sheet master.
In addition, also can use operation sheet master to make 2 operation sheets, use these 2 engineering sheets to make optical element.As the concrete grammar that uses 2 operation sheets, can enumerate following method (d)~(f).
(d) method comprises: form the face of concaveconvex shape in operation sheet master, metals such as plated with nickel, the operation of lamination coating (concaveconvex shape transfer printing material); Peel off this coating from operation sheet master, make the operation of metal 2 operation sheets; Then, in 2 operation sheets,, be coated with the operation of unhardened ionizing radiation hardening resin with the join face of side of concaveconvex shape; After the irradiation ionizing radiation makes described hardening resin sclerosis, from the operation of filming of 2 operation sheet strip hardened.
(e) method comprises: form the face of concaveconvex shape in operation sheet master, the operation of lamination coating (concaveconvex shape transfer printing material); Peel off this coating from operation sheet master, make the operation of metal 2 operation sheets; In these 2 operation sheets,, be coated with the operation of unhardened aqueous thermosetting resin with the join face of side of concaveconvex shape; After making this hardening of resin by heating, from the operation of filming of 2 operation sheet strip hardened.
(f) method comprises: form the face of concaveconvex shape in operation sheet master, the operation of lamination coating (concaveconvex shape transfer printing material); Peel off this coating from operation sheet master, make the operation of metal 2 operation sheets; In these 2 operation sheets with the join face of side of concaveconvex shape, the operation of contact sheet thermoplastic resin; When this thermoplastic resin is pressed in 2 operation sheets, after heating makes it softening, the operation of cooling off; Peel off the operation of the sheet thermoplastic resin of this cooling from 2 operation sheets.
The concrete example of illustration method (a).As shown in Figure 7, in tabular operation sheet master 110, form the face of concaveconvex shape 112a, be coated with unhardened aqueous ionizing radiation hardening resin 112c with coating machine (coater) 120.Then, the mode of rolling roll (roll) 130 is pushed the operation sheet master 110 that scribbles this hardening resin, with the concaveconvex shape 112a inside of described hardening resin filling in operation sheet master 110.With ionization radiation exposure device 140 irradiation ionizing radiations, make hardening resin crosslinked, sclerosis thereafter.Then, the ionizing radiation hardening resin after operation sheet master 110 strip hardened, thus can make tabular optical element 150.
In the method (a), for demoulding functions is provided, in operation sheet master, form on the face of concaveconvex shape, be coated with before the unhardened ionizing radiation hardening resin, thickness can be set be the layer that silicone resin about 1~10nm, fluororesin etc. are formed.
As the coating machine that is coated with unhardened ionizing radiation hardening resin on the face that in operation sheet master, forms concaveconvex shape, can enumerate T mould coating machine (T-DIE coater), roll-coater (roll coater), excellent coating machine (bar coater) etc.
As unhardened ionizing radiation hardening resin, can enumerate and comprise from epoxy acrylate, the epoxidized oil acrylate, urethane acrylate, unsaturated polyester (UP), polyester acrylate, polyether acrylate, ethene/acrylic ester, polyenoid/acrylate, Si acrylate, polybutadiene, prepolymers such as polystyrene methyl methacrylate, aliphatic acrylate, the ester ring type acrylate, the aromatic series acrylate, the hydroxy acryl acid ester, contain aryl-acrylic acid esters, contain the glyceryl acrylate, contain the carboxy acrylic ester, the material of 1 above composition of kind selecting among the monomers such as halogen-containing acrylate.Unhardened ionizing radiation hardening resin is preferably with dilutions such as solvents.
In addition, in unhardened ionizing radiation hardening resin, also can add fluororesin, silicone resin etc.
When unhardened ionizing radiation hardening resin being hardened, preferably, in unhardened ionizing radiation hardening resin, add photopolymerization initiators such as acetophenones, benzophenone with ultraviolet ray.
After coating unhardened aqueous ionizing radiation hardening resin, shine ionizing radiation behind the base material of the compositions such as resin, glass of can fitting.Ionizing radiation can be from any one party irradiation among base material with ionizing radiation permeability, the operation sheet master.
The thickness of the sheet of the ionizing radiation hardening resin after the sclerosis is preferably about 0.1~100 μ m.If the thickness of the sheet of the ionizing radiation hardening resin after the sclerosis is more than the 0.1 μ m, then can guarantee full intensity, if be more than the 100 μ m, then can guarantee sufficient reelability.
In the above-mentioned method shown in Figure 7, engineering sheet master is tabular, but also can be the sheet of individual (piece Leaf).When using individual sheet, can use mold pressing (stamp) method that individual sheet is used as the tabular mould, individual sheet is rolled into cylinder (roll) changes stamped method (roll in print) etc. over to as what cylindric mould used.In addition, individual operation sheet master can be disposed at the inboard of the mould of emission forming machine.
But these use in individual the method for sheet, for mass-producing optical elements, need repeatedly be recycled and reused for the operation that forms concaveconvex shape.Under the bad situation of the release property between ionizing radiation hardening resin and the operation sheet master, on concaveconvex shape, can produce after repeatedly repeating and stop up, there is the incomplete trend of transfer printing of concaveconvex shape.
In contrast to this, in method shown in Figure 7,, can large tracts of land form concaveconvex shape continuously because operation sheet master is tabular, so, though the repeated use number of times of concaveconvex shape formation sheet is few, also can make the optical element of aequum at short notice.
Among method (b), (e),, for example, can enumerate unhardened melamine resin, urethanes (urethane) resin, epoxy resin etc. as aqueous thermosetting resin.
In addition, the hardening temperature in the method (b) preferably is lower than the glass transition temperature of operation sheet master.This is because if hardening temperature is more than the glass transition temperature of operation sheet master, the concaveconvex shape of operation sheet master may be out of shape when then hardening.
Among method (c), (f),, for example, can enumerate acryl resin, polyolefin, polyester etc. as thermoplastic resin.
Pressure when the sheet thermoplastic resin is pressed in 2 operation sheets is preferably 1~100MPa.If the pressure when pushing is more than the 1MPa, then transfer printing concaveconvex shape accurately if be below the 100MPa, then can prevent undue pressurization.
In addition, the heating-up temperature of the thermoplastic resin in the method (c) preferably is lower than the glass transition temperature of operation sheet master.This is because if heating-up temperature is more than the glass transition temperature of operation sheet master, the concaveconvex shape of operation sheet master may be out of shape when then heating.
As the chilling temperature after the heating, for transfer printing concaveconvex shape accurately, preferably less than the glass transition temperature of thermoplastic resin.
Also can omit heating in method (a)~(c), consideration can prevent this point of distortion of the concaveconvex shape of operation sheet master, and preferred methods is for using the method (a) of ionizing radiation hardening resin.
In method (d)~(f), the thickness of metal 2 operation sheets is preferably about 50~500 μ m.If the thickness of metal 2 operation sheets is more than the 50 μ m, then 2 operation sheets have full intensity, if be below the 500 μ m, then can guarantee sufficient reelability.
In method (d)~(f), use the little metal film-making of the hot distortion that causes as the operation sheet, so form the material that sheet is used, can use ionizing radiation hardening resin, thermosetting resin, thermoplastic resin arbitrarily as concaveconvex shape.
In addition, be that concaveconvex shape with operation sheet master is transferred to metal and obtains the operation sheet 2 times in (d)~(f), obtain the operation sheet 2 times but also can be transferred to resin.As operable resin in this case, for example, can enumerate polycarbonate, polyacetal, polysulfones and the ionizing radiation hardening resin that in method (a), uses etc.When using the ionizing radiation hardening resin, with method (a) similarly, carry out successively the ionizing radiation hardening resin coating, harden, peel off, obtain the operation sheet 2 times.
For the optical element that obtains by as above method, can on face that forms concaveconvex shape and opposing face, adhesive phase be set.And, on face that forms concaveconvex shape and opposing face, also can further form concaveconvex shape.
In addition, can not peel off as concaveconvex shape formation sheet or 2 operation sheets that operation sheet master uses, but use, before using optical element, peel off protective seam as protective seam.
(embodiment)
Young modulus in the following example is, use stretching testing machine (the system テ of オ リ エ Application テ Star Network Co., Ltd. Application シ ロ Application RTC-1210), measured value when in " the metal material Young modulus test method under the high temperature " of JIS Z 2280-1993, temperature being changed to 23 ℃.When hard layer is made up of metallic compound too.
(Production Example 1)
In one side to the polyethylene terephthalate shrink film (the system ヒ シ ペ of Mitsubishi Plastics Inc Star ト LX-10S) of the Young modulus 3GPa of the thickness 50 μ m of a direction of principal axis thermal shrinkage, the vacuum evaporation Young modulus is the titanium of 115GPa, its thickness is 3nm, form the surface smoothing hard layer, obtain laminate.
Then, this laminate was heated 1 minute in 100 ℃, making its thermal shrinkage is 40% (that is, the deformation rate distortion with 60%) of length before heating, and obtains forming along the direction of relative shrinkage direction quadrature at hard layer the concaveconvex shape formation sheet of the wavy concaveconvex shape of periodicity.
(Production Example 2)
Except the thickness of the titanium of vacuum evaporation was 7nm, other and Production Example 1 were same, obtain concaveconvex shape and form sheet.
(Production Example 3)
Laminate was heated 1 minute in 75 ℃, make its thermal shrinkage for heating before 70% (that is) of length with the distortion of 30% deformation rate, in addition, other is same with Production Example 1, obtains concaveconvex shape formation sheet.
(Production Example 4)
Replace ヒ シ ペ Star ト LX-10S, use is to the polyethylene terephthalate shrink film (the system ヒ シ ペ of Mitsubishi Plastics Inc Star ト PX-40S) of the Young modulus 3GPa of the thickness 50 μ m of two direction of principal axis thermal shrinkages, in addition, other and Production Example 1 are same, obtain concaveconvex shape and form sheet.The concaveconvex shape of Production Example 4 forms sheet, forms not wavy concaveconvex shape along specific direction at hard layer.
(Production Example 5)
Replace the vacuum evaporation titanium, the vacuum evaporation Young modulus is the platinum of 168GPa, and its thickness is 3nm, and in addition, other is same with Production Example 1, obtains concaveconvex shape formation sheet.
(Production Example 6)
Replace the vacuum evaporation titanium, the vacuum evaporation Young modulus is the silicon dioxide of 72Gpa, and its thickness is 3nm, and in addition, other is same with Production Example 1, obtains concaveconvex shape formation sheet.
(Production Example 7)
Replace the vacuum evaporation titanium, the vacuum evaporation Young modulus is the titania of 300GPa, and its thickness is 1nm, and in addition, other is same with Production Example 1, obtains concaveconvex shape formation sheet.The organic self-cleaning function that the breakdown face adhered to when this concaveconvex shape formation sheet had rayed.
(Production Example 8)
Replace the vacuum evaporation titanium, the chemical vapor deposition Young modulus is the gallium arsenide of 83GPa, and its thickness is 3nm, and in addition, other is same with Production Example 1, obtains concaveconvex shape formation sheet.
(Production Example 9)
With Young modulus is the sheet of the thickness 5mm that forms of the dimethyl silicone polymer of 2MPa, is stretched to 2 times length with stretching device, and is fixed in this state.Then, under this state, the vacuum evaporation Young modulus is the titanium of 115GPa on the one side of this sheet, and its thickness is 3nm, forms the surface smoothing hard layer, obtains laminate.
Then, stop stretching, make this laminate get back to stretching length before, like this, the deformation rate compression hard layer with 50% obtains at the concaveconvex shape formation sheet of hard layer along the wavy concaveconvex shape of direction formation periodicity of relative compression direction quadrature.
(Production Example 10)
In Young modulus is the one side of the sheet of the thickness 5mm that forms of the dimethyl silicone polymer of 2MPa, and the vacuum evaporation Young modulus is the titanium of 115GPa, and its thickness is 3nm, obtains the laminate of resin bed and surface smoothing hard layer lamination.
Then, with stretching device laminate is stretched to 5 times length, make the length of the normal direction of draw direction shrink 50% (that is, the deformation rate distortion with 50%), the concaveconvex shape of wavy concaveconvex shape forms sheet to obtain forming periodically at hard layer along draw direction.
(Production Example 11)
Except the thickness of the titanium of vacuum evaporation was 15nm, other and Production Example 1 were same, obtain concaveconvex shape and form sheet.
(Production Example 12)
Replace shrink film, the Young modulus of used thickness 50 μ m is two of 5GPa and extends polyethylene terephthalate film (the system G2 of Teijin Ltd), in addition, and the method that other and Production Example 1 are same, trial obtains concaveconvex shape and forms sheet, does not form sheet but obtain concaveconvex shape.
(Production Example 13)
In the Young modulus to the thickness 50 μ m of a direction of principal axis thermal shrinkage is the one side of the polyethylene terephthalate shrink film (the system ヒ シ ペ of Mitsubishi Plastics Inc Star ト LX-10S) of 3GPa, the vacuum evaporation Young modulus is the titanium of 115GPa, its thickness is 3nm, form the surface smoothing hard layer, obtain laminate.
Then, this laminate was heated 1 minute in 70 ℃, make it be punctured into 97% (that is, with the distortion of 3% deformation rate) of length before the heating, in addition, other is same with Production Example 1, obtains concaveconvex shape formation sheet.
(Production Example 14)
The concaveconvex shape that use is obtained by Production Example 1 forms sheet as operation sheet master, obtains optical element by the following method.
Promptly, in the operation sheet master that obtains by Production Example 1, form the face of concaveconvex shape, coat unhardened uv-hardening resin constituent, this uv-hardening resin constituent comprises: epoxy acrylate is prepolymer, 2-EHA and benzophenone series photopolymerization initiator.
Then, the face that in the filming of unhardened uv-hardening resin constituent, does not join with operation sheet master, overlapping thickness is the tri acetyl cellulose membrane of 50 μ m, and it is pushed.
Then,, make unhardened uv-hardening resin sclerosis, peel off the layered product of this hardening thing and triacetyl cellulose, obtain optical element from operation sheet master from tri acetyl cellulose membrane top irradiation ultraviolet radiation.
(Production Example 15)
The concaveconvex shape that use is obtained by Production Example 1 forms sheet as operation sheet master, obtains optical element as follows.
That is, form the face nickel plating of concaveconvex shape in the operation sheet master that is obtained by Production Example 1, peel off this nickel coating, obtaining thickness is the nickel plating sheet of 200 μ m.The face of the side of in this nickel plating sheet, joining with operation sheet master, coat unhardened uv-hardening resin constituent, this uv-hardening resin constituent comprises: epoxy acrylate is prepolymer, 2-EHA and benzophenone series photopolymerization initiator.
Then, the face that in the filming of unhardened uv-hardening resin constituent, does not join with nickel plating sheet, overlapping thickness is the tri acetyl cellulose membrane of 50 μ m, and it is pushed.
Then,, make unhardened uv-hardening resin sclerosis, plate the layered product that sheet is peeled off this hardening thing and triacetyl cellulose, obtain optical element from nickel from tri acetyl cellulose membrane top irradiation ultraviolet radiation.
(Production Example 16)
Replace the uv-hardening resin constituent to use thermosetting epoxy resin, replace irradiation ultraviolet radiation to make this thermosetting epoxy cure by heating, in addition, other and Production Example 14 are same, obtain optical element.
(Production Example 17)
According to the method same with Production Example 14, obtaining thickness is the nickel plating sheet of 200 μ m.The face of the side of in this nickel plating sheet, joining with operation sheet master, overlapping thickness is the polyacrylamide film of 50 μ m, and to its heating.Thermoplastic polyacrylamide film and nickel are plated sheet, and after pushing from their both sides, cooling, curing are peeled off the polyacrylamide film of curing from nickel plating sheet, obtain optical element.
Above atomic force microscope (the Japanese PVC system Na ノ ス コ one プ III of one コ society) the concaveconvex shape formation sheet of shooting Production Example 1~11,13 and the optical element of Production Example 14~17.
For the concaveconvex shape formation sheet of Production Example 1,5~11,13 and the optical element of Production Example 14~17, in the image of atomic force microscope, measure the spacing of 10 place's concaveconvex shapes, these spacings are averaged obtain average headway.
The concaveconvex shape of Production Example 4 forms the average headway of sheet, and the image of being put down in writing with~the 9 page of the 4th row of the 8th page of the 24th row of this instructions to concaveconvex shape carries out the method for Fourier transform and obtains.
In addition, form the mean depth of the optical element of sheet and Production Example 14~17 for the concaveconvex shape of Production Example 1~11,13, in the cross-section image that obtains by atomic force microscope, measure the degree of depth of each bottom of 10 place's concaveconvex shapes, these degree of depth are averaged obtain mean depth.These values are as shown in table 1.
And, according to the average headway of concaveconvex shape and the mean depth of bottom, whether be suitable as optical element with following benchmark evaluation.Evaluation result is as shown in table 1.
Zero: the average headway of concaveconvex shape is that mean depth is suitable as optical element for average headway is used as 100% o'clock more than 10% below the 1 μ m.
*: the average headway of concaveconvex shape surpasses 1 μ m, perhaps, mean depth less than average headway is used as 100% o'clock 10%, be not suitable as optical element.
Table 1:
The spacing of concaveconvex shape (nm) The innermost degree of depth (nm) in the concaveconvex shape The degree of depth/spacing (%) Estimate
Production Example 1 300 300 100
Production Example 2 700 700 100
Production Example 3 300 90 30
Production Example 4 300 250 83
Production Example 5 250 250 100
Production Example 6 200 200 100
Production Example 7 250 250 100
Production Example 8 220 220 100
Production Example 9 300 200 67
Production Example 10 300 200 67
Production Example 11 1100 700 64 ×
Production Example 12 Do not form concaveconvex shape ×
Production Example 13 300 28 9 ×
Production Example 14 300 300 100
Production Example 15 300 300 100
Production Example 16 300 300 100
Production Example 17 300 300 100
According to the manufacture method of Production Example 1~11,13, promptly the one side at resin bed is provided with the method that the laminate of the surface smoothing hard layer that metal or metallic compound form is shunk or compress, easily produced concaveconvex shape formation sheet.Particularly, the concaveconvex shape that obtains in Production Example 1~10 forms sheet, and the average headway of concaveconvex shape is that the mean depth of bottom is suitable as optical element for described average headway is used as 100% o'clock more than 10% below the 1 μ m.Obtaining aforesaid average headway and mean depth in Production Example 1~10 is because the thickness of surface smoothing hard layer is that the following Young modulus of 10nm is low, and deformation rate is more than 30%.
In addition, in Production Example 11, because the thickness of surface smoothing hard layer surpasses 10nm, so the concaveconvex shape that obtains forms in the sheet, the average headway of concaveconvex shape surpasses 1 μ m.In addition, in Production Example 13 because deformation rate is 3%, thus the concaveconvex shape that obtains form in the sheet, the mean depth of the bottom of concaveconvex shape less than average headway is used as 100% o'clock 10%.These not necessarily are suitable as optical element.
In addition, according to using the concaveconvex shape that obtains in the Production Example 1 to form the manufacture method of sheet as the Production Example 14~17 of operation sheet master, can produce optical element easily, this optical element is formed with concaveconvex shape and forms the average headway that sheet equates and the concaveconvex shape of mean depth.
Relatively therewith, using two to extend in the Production Example 12 of polyethylene terephthalate film as resin bed, the distortion because the surface smoothing hard layer does not crawl is not so form concaveconvex shape.
Concaveconvex shape of the present invention forms sheet can be used in for example Polarizer, grinding film, cellular incubation sheet, electrolyte membrane for fuel cell, mold release film, Antiadhesive film, highly adhesive film, printing raising film etc.In addition, a plurality of in also can the dual-purpose such use.
The above only is preferred embodiment of the present invention, and is in order to restriction the present invention, within the spirit and principles in the present invention not all, any modification of being done, is equal to replacement, improvement etc., all should be included within protection scope of the present invention.

Claims (13)

1, a kind of concaveconvex shape forms sheet, comprises the hard layer of resin bed and at least a portion that is arranged on this resin bed outside, forms wavy concaveconvex shape at this hard layer, it is characterized in that,
Hard layer is made up of metal or metallic compound;
The average headway of concaveconvex shape is that the mean depth of the bottom of concaveconvex shape is for to be used as described average headway as 100% o'clock more than 10% below the 1 μ m.
2, concaveconvex shape according to claim 1 forms sheet, and wherein, hard layer is made up of metallic compound.
3, concaveconvex shape according to claim 2 forms sheet, wherein, metallic compound is, at least a kind of metallic compound selecting among the group who forms from titanium dioxide, aluminium oxide, zinc paste, magnesium oxide, tin oxide, cupric oxide, indium oxide, cadmium oxide, massicot, monox, barium fluoride, calcium fluoride, magnesium fluoride, zinc sulphide, gallium arsenide.
4, concaveconvex shape according to claim 1 forms sheet, and wherein, hard layer is made up of metal.
5, concaveconvex shape according to claim 4 forms sheet, and wherein, metal is, at least a kind of metal of selection among the group who forms from gold, aluminium, silver, carbon, copper, germanium, indium, magnesium, niobium, palladium, lead, platinum, silicon, tin, titanium, vanadium, zinc, bismuth.
6, a kind of concaveconvex shape forms the manufacture method of sheet, it is characterized in that this method comprises following operation:
At least a portion in the resin bed outside is provided with the hard layer of surface smoothing, the operation of cambium layer compressing tablet; At least make the crawl operation of distortion of the hard layer of this laminate;
Wherein, hard layer constitutes with metal or metallic compound.
7, a kind of antireflection object, wherein, wantonly 1 described concaveconvex shape that this antireflection object has in the claim 1~5 forms sheet.
8, a kind of polarizer, wherein, wantonly 1 described concaveconvex shape that this polarizer has in the claim 1~5 forms sheet.
9, wantonly 1 described concaveconvex shape that a kind of operation sheet master, this operation sheet master have in the claim 1~5 forms sheet; This operation sheet master uses as mould, and this mould is used to make the sheet of the concaveconvex shape that forms the average headway that equates with this concaveconvex shape formation sheet and mean depth.
10, a kind of manufacture method of optical element, this method comprises following operation:
In the described operation sheet of claim 9 master, form the face of concaveconvex shape, be coated with the operation of unhardened hardening resin;
After making this hardening resin sclerosis, from the operation of filming of operation sheet master strip hardened.
11, a kind of manufacture method of optical element, this method comprises following operation:
In the described operation sheet of claim 9 master, form the face of concaveconvex shape, the operation of the thermoplastic resin of contact sheet;
When this thermoplastic resin is pressed in operation sheet master, after heating makes it softening, the operation of cooling off;
Peel off the operation of the sheet thermoplastic resin of cooling from operation sheet master.
12, a kind of manufacture method of optical element, this method comprises following operation:
In the described operation sheet of claim 9 master, form the face of concaveconvex shape, the lamination concaveconvex shape transfer printing operation of material;
From the peeling laminated concaveconvex shape transfer printing material of described operation sheet master, make the operation of 2 operation sheets at concaveconvex shape;
The face of the side of joining with the concaveconvex shape of described operation sheet master in these 2 operation sheets is coated with the operation of unhardened hardening resin;
After making this hardening resin sclerosis, from the operation of filming of 2 operation sheet strip hardened.
13, a kind of manufacture method of optical element, this method comprises following operation:
In the described operation sheet of claim 9 master, form the face of concaveconvex shape, the lamination concaveconvex shape transfer printing operation of material;
From the peeling laminated concaveconvex shape transfer printing material of described operation sheet master, make the operation of 2 operation sheets at concaveconvex shape;
The face of the side of in these 2 operation sheets, joining with the concaveconvex shape of described operation sheet master, the operation of the thermoplastic resin of contact sheet;
When this thermoplastic resin is pressed in 2 operation sheets, after heating makes it softening, the operation of cooling off;
Peel off the operation of the sheet thermoplastic resin of cooling from 2 operation sheets.
CNA2007101017616A 2006-05-10 2007-05-08 Corrugated pattern forming sheet and method for manufacturing the same, and method for manufacturing antireflector, retardation plate, original process sheet plate, and optical element Pending CN101071183A (en)

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Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102401924A (en) * 2011-12-01 2012-04-04 明基材料有限公司 Patterned phase retardation film and method for manufacturing the same
CN102859397A (en) * 2010-04-13 2013-01-02 旭化成电子材料株式会社 Self-supporting film, self-supporting structure, method for manufacturing self-supporting film, and pellicle
CN103135224A (en) * 2013-03-25 2013-06-05 武汉工程大学 Preparation method for light-operated reversible wetting coating
CN103518422A (en) * 2011-04-27 2014-01-15 吉坤日矿日石能源株式会社 Light extraction transparent substrate for organic electroluminescent element and organic electroluminescent element using same
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CN109728197A (en) * 2019-01-02 2019-05-07 京东方科技集团股份有限公司 Display base plate and preparation method thereof and display device
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Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS62102445A (en) * 1985-10-28 1987-05-12 Nippon Sheet Glass Co Ltd Production of optical disk substrate
JP2002286906A (en) * 2001-03-23 2002-10-03 Mitsubishi Chemicals Corp Antireflection method, antireflection structure and antireflection structural body having antireflection structure and method for manufacturing the same
CN1093265C (en) * 1997-03-14 2002-10-23 株式会社三协精机制作所 Diffracting grating and its manufacture

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS62102445A (en) * 1985-10-28 1987-05-12 Nippon Sheet Glass Co Ltd Production of optical disk substrate
CN1093265C (en) * 1997-03-14 2002-10-23 株式会社三协精机制作所 Diffracting grating and its manufacture
JP2002286906A (en) * 2001-03-23 2002-10-03 Mitsubishi Chemicals Corp Antireflection method, antireflection structure and antireflection structural body having antireflection structure and method for manufacturing the same

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CN102401924A (en) * 2011-12-01 2012-04-04 明基材料有限公司 Patterned phase retardation film and method for manufacturing the same
CN103135224B (en) * 2013-03-25 2015-03-18 武汉工程大学 Preparation method for light-operated reversible wetting coating
CN103135224A (en) * 2013-03-25 2013-06-05 武汉工程大学 Preparation method for light-operated reversible wetting coating
CN104777544A (en) * 2015-04-29 2015-07-15 深圳市华星光电技术有限公司 Polarizer and preparation method and liquid crystal display panel thereof
CN104777544B (en) * 2015-04-29 2017-08-11 深圳市华星光电技术有限公司 Polaroid and preparation method thereof, liquid crystal panel
CN110014679A (en) * 2018-01-10 2019-07-16 柯尼卡美能达株式会社 The manufacturing method of stretched film
CN110014679B (en) * 2018-01-10 2021-09-14 柯尼卡美能达株式会社 Method for producing stretched film
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US11716888B2 (en) 2019-01-02 2023-08-01 Chengdu Boe Optoelectronics Technology Co., Ltd. Display substrate comprising scattering structure formed in anode and including plurality of mutually staggered grooves, method for preparing the same, and display device
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