JP4167023B2 - Transparent conductive laminate for touch panel - Google Patents

Description

ＰＥＴ：ポリエチレンテレフタレート
ＰＣ：ポリカーボネート
比抵抗２、透過率２は１３０℃４時間の熱処理後の値
比抵抗の単位はΩ・ｃｍ、透過率の単位は％、Ｘ線回折強度の規格化強度の単位はｃｐｓ／ｎｍ／ｋＷ、結晶粒径の単位はｎｍ
【００６７】
［実施例６］
実施例５の試料の（２２２）面からのＸ線回折強度をＸ線源への投入電力を６．４ｋＷ（４０ｋＶ、１６０ｍＡ）として測定した。その結果得られたＸ線回折強度の規格化強度は、２１ｃｐｓ／ｎｍ／ｋＷであった。これは、Ｘ線源への投入電力と（２２２）面からのＸ線回折強度がほぼ比例していることを示している。
【００６８】
［比較例１］
実施例１と同じコーティングを施したポリエチレンテレフタレート基板を用いて、到達真空度を１．３Ｅ−５Ｐａ以下とした後、酸素を３．３Ｅ−３Ｐａ導入した。そこへ、プロセスガスとしてＡｒを導入し全圧を０．４Ｐａとした。そして、５ｗｔ％の酸化錫を含む酸化インジウム焼結ターゲットに１Ｗ／ｃｍ²の電力密度で電力を投入し、ＤＣマグネトロンスパッタリング法により、反射防止層上へ、透明導電膜を２０ｎｍ積層した。この積層体の、成膜直後の比抵抗は６．０Ｅ−４Ω・ｃｍであり、全光線透過率は８４％であった。
【００６９】
この積層体を１３０℃の恒温槽中で４時間熱処理を行った。その結果、比抵抗は６．５Ｅ−４Ω・ｃｍであり、全光線透過率は８５％であった。Ｘ線回折強度の規格化強度は５ｃｐｓ／ｎｍ／ｋＷであった。透過型電子顕微鏡にて観察した結晶粒径は約１５００ｎｍであった。筆記耐久性の結果、透明導電膜が削れ始めていた。さらに抵抗値がタッチパネル用途としては低減しすぎていた。
【００７０】
［比較例２］
実施例１と同じコーティングを施したポリエチレンテレフタレート基板を用いて、到達真空度を１．３Ｅ−５Ｐａ以下とした後、酸素を１．３Ｅ−２Ｐａ導入した。そこへ、プロセスガスとしてＡｒを導入し全圧を０．４Ｐａとした。そして、１ｗｔ％の酸化錫を含む酸化インジウム焼結ターゲットに１Ｗ／ｃｍ²の電力密度で電力を投入し、ＤＣマグネトロンスパッタリング法により、反射防止層上へ、透明導電膜を２０ｎｍ積層した。この積層体の、成膜直後の比抵抗は２．０Ｅ−３Ω・ｃｍであり、全光線透過率は８８％であった。
【００７１】
この積層体を１３０℃の恒温槽中で４時間熱処理を行った。その結果、比抵抗は２．２Ｅ−３Ω・ｃｍであり、全光線透過率は８８％であった。Ｘ線回折強度の規格化強度は７５ｃｐｓ／ｎｍ／ｋＷであった。透過型電子顕微鏡にて観察した結晶粒径は約６０ｎｍであった。透明導電積層体にクラックが発生した。筆記耐久性の結果、透明導電膜が剥がれ始めていた。
【００７２】
［比較例３］
実施例１と同じコーティングを施したポリエチレンテレフタレート基板を用いて、到達真空度を６．７Ｅ−４Ｐａ以下とした後、酸素を１．３Ｅ−２Ｐａ導入した。そこへ、プロセスガスとしてＡｒを導入し全圧を０．４Ｐａとした。そして、５ｗｔ％の酸化錫を含む酸化インジウム焼結ターゲットに４Ｗ／ｃｍ²の電力密度で電力を投入し、ＤＣマグネトロンスパッタリング法により、反射防止層上へ、透明導電膜を２０ｎｍ積層した。この積層体の、成膜直後の比抵抗は１．０Ｅ−３Ω・ｃｍであり、全光線透過率は８７％であった。
【００７３】
この積層体を１３０℃の恒温槽中で４時間熱処理を行った。その結果、比抵抗は１．２Ｅ−３Ω・ｃｍであり、全光線透過率は８８％であった。Ｘ線回折強度の規格化強度は３ｃｐｓ／ｎｍ／ｋＷであった。透過型電子顕微鏡にて観察した結晶粒径は約６０ｎｍであった。筆記耐久性の結果、透明導電膜が剥がれ始めていた。
【００７４】
【発明の効果】
以上説明したように、本発明によれば、規格化強度および膜厚を一定の範囲にした透明導電膜を高分子フィルム上に形成した透明導電積層体は、筆記耐久性の良好なタッチパネル用として極めて有用である。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a transparent conductive laminate suitable for a touch panel, and more particularly to a transparent conductive laminate for a touch panel having a crystalline transparent conductive film excellent in writing durability.
[0002]
[Prior art]
In recent years, touch panels as input devices combined with liquid crystal display elements have become widespread. And it is widely used as a PDA device from a digital switch element to an analog recognition element by pen input.
[0003]
A touch panel is used by being superimposed on the upper side of a liquid crystal display element by a combination of a transparent conductive laminate using a glass substrate or a plastic substrate and a transparent conductive laminate using a PET substrate. Since this touch panel is usually outside the liquid crystal display element, it can be replaced relatively easily when the touch panel is broken, but the visibility tends to be slightly deteriorated and the brightness of the liquid crystal display element tends to be lowered. On the other hand, a touch panel in which a touch panel is formed inside a polarizing plate of a liquid crystal display element to improve visibility and brightness is being developed. In this case, it is necessary to use a plastic substrate having a small optical anisotropy.
[0004]
As described above, the touch panel is required to be lightweight and have high functionality such as improved visibility and ease of replacement. In addition, writing durability, which is an index for enduring an input load, is required for pen input.
[0005]
Actually, this writing durability is the most important function for a transparent conductive laminate for a touch panel, and even in such a present situation, improvements are made on a daily basis.
[0006]
[Problems to be solved by the invention]
Two methods are currently being investigated as measures to improve the writing durability of the touch panel. One is to improve the structure of the substrate. The other is an improvement of a transparent conductive film formed as a transparent electrode of a transparent conductive laminate for a touch panel. Although the former method is highly effective, it cannot be denied that it is necessary to introduce a new bonding step. In the latter case, it is necessary to properly grasp the characteristics of the transparent conductive film, and in particular, sufficient attention must be paid to the crystal state of the transparent conductive film. On the contrary, if the crystal state of the transparent conductive film is properly grasped, a transparent conductive film having extremely high writing durability can be obtained including reproducibility in the process.
[0007]
In other words, if a transparent conductive film typified by indium tin oxide having good quality crystals is supplied, it is expected that a transparent conductive laminate for a touch panel provided with a transparent conductive film having high writing durability can be supplied. It is shown that. Furthermore, this is a common phenomenon when the touch panel is formed on either the outside or the inside of the polarizing plate of the liquid crystal display element.
[0008]
An object of the present invention is to provide a transparent conductive laminate for a touch panel with improved writing durability by paying attention to crystallization of a transparent conductive film formed on the transparent conductive laminate for a touch panel.
[0009]
[Means for Solving the Problems]
In the transparent conductive laminate for a touch panel used in combination with a liquid crystal display element, the present inventors considered that it is important to use a transparent conductive film having higher crystallinity to improve writing durability. . As a result of intensive studies on indium oxide-based transparent conductive films having various compositions, surprisingly, in the X-ray diffraction measurement, the diffraction intensity from the (222) plane of indium oxide per unit film thickness exceeds a certain value. It has been found that writing durability is improved in a certain transparent conductive film.
[0010]
In an ordinary indium oxide-based transparent conductive film, indium oxide has a bixbite type crystal structure, and diffraction lines appearing in X-ray diffraction are mainly (222) plane, (400) plane, and (440) plane.
[0011]
In the present invention, analysis focusing on the (222) plane having the strongest X-ray diffraction line intensity was performed. This is because the (222) plane is the closest packed surface of the bixbite type crystal structure, and the crystallized indium oxide-based transparent conductive film can be expected to be most resistant to external stress.
[0012]
In the indium oxide transparent conductive film having a specific composition range, the present inventors can make the X-ray diffraction line intensity from the (222) plane a certain value or more, and at this time, the writing durability of the touch panel is remarkably high. It was found that it improved.
[0013]
However, the X-ray diffractometer has different power input to the X-ray generation source depending on the apparatus, and therefore it is difficult to evaluate the crystallinity with the absolute value of the diffraction line intensity. Further, it has been difficult to theoretically obtain the X-ray diffraction intensity for an indium oxide-based transparent conductive film which is a non-stoichiometric composition. Therefore, the present inventors considered to standardize the X-ray reflection intensity (in cps) from the (222) plane of indium oxide with the input power to the X-ray source.
[0014]
This is due to the following reason. The characteristic X-ray intensity from the X-ray source is proportional to the input power when the X-ray source is a tube made of a metal having a relatively low excitation energy for generating X-rays such as Co, Fe, Cu, and Ni. To do. The inventors have obtained that the characteristic X-ray intensity generated in the X-ray diffraction apparatus correlates with the input power to the X-ray source, and further obtained from the characteristic X-ray intensity and the transparent conductive film (222). ) It was found that the diffraction line intensity of the surface is proportional. This indicates that when the input power is doubled, the characteristic X-ray intensity is doubled and the obtained diffraction line intensity is approximately doubled. And we found that this phenomenon does not depend on the device, and got the chance to complete the present invention.
[0015]
Furthermore, it has been found that as the film thickness of the transparent conductive film to be measured increases, the diffraction intensity from the (222) plane increases in proportion to the film thickness. Then, if the diffraction line intensity from the (222) plane is normalized using the film thickness, the diffraction line intensity from the (222) plane of the transparent conductive film is separated from the parameter caused by the manufacturing of the film thickness. It can be staged up to a parameter that does not originate from the method and shows the intrinsic properties of the membrane.
[0016]
In this way, the original structure of the transparent conductive film can be evaluated and correlated with the writing durability by the two standardizations of the above-mentioned evaluation system parameter of input power to the X-ray source and manufacturing-derived parameter of film thickness. As a result, the present invention has been completed. However, it should be noted that the X-ray diffraction method is a concentrated method and the X-ray source is Co, Fe, Cu, N any of i and K Use alpha rays without making them monochromatic. (Solar slit, divergence slit, scattering slit, light receiving slit) It is to install and use a scintillation counter as a detector.
[0017]
That is, the present invention is a transparent conductive laminate for a touch panel in which a transparent conductive film mainly composed of substantially crystalline indium oxide is laminated on at least one surface of a polymer film. The reflection intensity from the (222) plane derived from the indium crystal is measured by the concentration method, and the obtained X-ray diffraction intensity (I) is divided by the film thickness (d) of the transparent conductive film, and further measurement is performed. In the transparent conductive laminate, the normalized intensity (I / d) / P divided by the input power (P) of the X-ray source of the X-ray diffractometer is 6 to 60 cps / nm / kW. The film thickness of the transparent conductive film is 10-30 nm A transparent conductive laminate for a touch panel. Here, the X-ray diffraction method is a concentration method, and the X-ray source is any one of Co, Fe, Cu, and Ni, and Kα rays are used without being monochromatic, solar slits, divergence slits, scattering slits, light reception A slit is installed and a scintillation counter is used as a detector. More The transparent conductive film in the transparent conductive laminate is mainly composed of indium oxide and contains 2 to 7.5% by weight of tin oxide, and the transparent conductive film in the transparent conductive laminate has a crystal grain size of 20 to 1000 nm. It is the transparent conductive laminated body for touch panels which is suitable.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described sequentially.
[0019]
Examples of the polymer film used in the present invention include thermoplastic polymers and curable polymers. Among them, for example, polyester polymers such as polyethylene terephthalate and polyethylene 2,6 naphthalate, polyolefin polymers, and thermoplastic polymers such as polycarbonate, polyethersulfone, and polyarylate are exemplified. Two or more of these may be used in combination. In order to impart an optical function or a thermodynamic function, a copolymerized polymer obtained by copolymerizing these polymers with the second and third components can be used.
[0020]
In particular, polyethylene terephthalate in which a film is formed by a melt extrusion method is suitable for a device that requires strong mechanical properties such as writing durability such as a touch panel. Moreover, when using a touch panel as a device in which optical characteristics are regarded as important, polycarbonate having a bisphenol component, which will be described later, and favorable transparency is preferable. The polycarbonate is preferably polymerized by the phosgene method and formed into a film by the casting method. Moreover, WO00 / 26705 was referred for the polymerization method of the copolymer polycarbonate and the film formation method.
[0021]
Examples of the bisphenol component include 2,2-bis (4-hydroxyphenyl) propane (bisphenol A), 1,1-bis (4-hydroxyphenyl) cyclohexane (bisphenol Z), and 1,1-bis (4- Hydroxyphenyl) -3,3,5-trimethylcyclohexane, 9,9-bis (4-hydroxyphenyl) fluorene, 9,9-bis (3-methyl-4-hydroxyphenyl) fluorene.
[0022]
Two or more of these may be combined. That is, the polycarbonate may be a copolymer polycarbonate or a blend.
[0023]
Furthermore, a polymer obtained by blending a plurality of polymers can be used in order to develop a new function. Furthermore, a multilayer coextruded polymer film can be used as the polymer film used in the present invention.
[0024]
Moreover, as a thickness of a polymer film, the thing of 0.01-0.4 mm can be used, However About 0.05-0.2 mm is desirable from a viewpoint of mechanical strength as a touch-panel use. In addition, after forming a transparent conductive film on a polymer film of about 0.01 mm, it is bonded to another polymer film with a large thickness via an adhesive to make the entire film thickness 0.1 to 0.2 mm. May be used.
[0025]
The transparent conductive laminate of the present invention is formed on the polymer film and at least one surface thereof, but the adhesion with the transparent conductive film is improved, the durability of the polymer film is improved, or the transmittance of the polymer film is increased. In order to improve, a coating layer composed of at least one layer may be provided between the polymer film and the transparent conductive film and / or on the surface opposite to the surface on which the transparent conductive film is formed. .
[0026]
This coating layer consists of an inorganic substance, an organic substance, or those composite materials, and the film thickness is preferably 0.01 to 20 μm. More desirably, it is desirably suppressed to about 10 μm. For forming the coating layer, a coating method using a coater, a spray method, a spin coating method, an in-line coating method and the like are often used, but this is not restrictive. Also, a method of physical vapor deposition (hereinafter referred to as PVD) or chemical vapor deposition (hereinafter referred to as CVD) such as sputtering or vapor deposition may be used.
[0027]
As a material for forming the coating layer, for example, a resin component such as an acrylic resin, a urethane resin, a UV curable resin, and an epoxy resin, or a mixture of these with inorganic particles such as alumina, silica, mica may be used. . As the particle size of the mixed inorganic particles, ultrafine particles having a size of about several nm can be used. Alternatively, as described above, the function of the coating layer may be provided by coextrusion of two or more polymer films.
[0028]
A coating layer can also be provided using PVD and CVD techniques. For example, oxides such as magnesium oxide, aluminum oxide, silicon oxide, calcium oxide, barium oxide, tin oxide, indium oxide, tantalum oxide, titanium oxide, and zinc oxide, and nitrides such as silicon nitride, titanium nitride, and tantalum nitride, An oxynitride such as silicon oxynitride or a fluoride or a fluoride such as magnesium fluoride or calcium fluoride can be formed and used. The transparent conductive laminate having such a coating layer desirably has low retardation and high transmittance as optical characteristics. Of course, the base of the coating layer formed by PVD and CVD methods is composed of various organic / inorganic materials and mixtures to improve adhesion, adjust transmittance, and improve durability. You may have a layer.
[0029]
In order to increase the light transmittance in order to improve visibility, a configuration in which an optical interference layer is provided directly below the transparent conductive film is desirable. More specifically, for example, a layer containing ultrafine titanium oxide can be provided as a high refractive index layer, and a layer containing ultrafine silicon oxide can be formed thereon to form a desired optical interference layer. Due to the effect of this optical interference layer, the transparent laminate before forming the transparent conductive film can exhibit a total light transmittance of nearly 90%.
[0030]
Furthermore, a hard coat layer may be provided under the optical interference layer in order to provide an effect of assisting the writing durability of the transparent conductive film and to further improve the writing durability. As the hard coat layer, a thermosetting resin or a radiation curable resin can be used. Specifically, organosilane thermosetting resins such as methyltriethoxysilane, melamine thermosetting resins such as etherified methylol melamine, and polyfunctional acrylate UV curable resins such as polyester acrylate can be used. This hard coat layer may be utilized as an anti-Newton ring layer by simultaneously adding a filler. Furthermore, it may be used as an antiglare layer.
[0031]
The transparent conductive laminate of the present invention is obtained by forming a transparent conductive film on at least one surface, that is, one surface or both surfaces of a polymer film. Preferably, the transparent conductive film is made of indium oxide containing 2 to 7.5% by weight of tin oxide. When tin oxide is less than 2% by weight, crystallization is likely to occur, but crystallization easily occurs even at room temperature. As a result, cracks are generated in the transparent conductive film in the touch panel manufacturing process. On the other hand, if the tin oxide exceeds 7.5% by weight, crystallization hardly occurs and writing durability deteriorates. More preferably, it is indium oxide containing 2 to 5% by weight of tin oxide, and particularly preferable is indium oxide containing 3 to 5% by weight of tin oxide.
[0032]
As a method for forming a transparent conductive film in the present invention, for example, a DC magnetron sputtering method, an RF magnetron sputtering method, an ion plating method, a vacuum deposition method, a pulse laser deposition method, a formation method combining these, or the like may be used. However, the DC magnetron sputtering method is desirable in view of industrial productivity of forming a transparent conductive film having a uniform film thickness over a large area.
[0033]
The target used for sputtering is preferably an oxide sintered target in which tin oxide is added in an amount of 2 to 7.5% by weight based on indium oxide, but an alloy target in which metallic tin is added to metallic indium is used. A sputtering method may be used.
[0034]
In this invention, when forming the said transparent conductive film by DC magnetron sputtering method using an oxide sintering target, the pressure (back pressure) in the vacuum chamber which forms this transparent conductive film is once 1.3 times. × 10 ^-Four It can be formed by a manufacturing method in which the pressure is set to Pa or less and then an inert gas and oxygen are introduced. The pressure in the vacuum chamber for forming the transparent conductive film is 1.3 × 10 once. ^-Four Setting it to Pa or less is desirable because it can reduce the influence of molecular species remaining in the vacuum chamber and fearing to affect the characteristics of the transparent conductive film. More desirably, 5 × 10 ^-Five Pa or less, more desirably 2 × 10 ^-Five Pa or less.
[0035]
As the inert gas introduced next, for example, He, Ne, Ar, Kr, and Xe can be used, and it is said that an inert gas having a larger atomic weight causes less damage to the formed film and improves surface flatness. ing. However, Ar is desirable from the viewpoint of cost. In order to adjust the oxygen concentration taken into the film, this inert gas is converted into partial pressure of 1.3 × 10 ^-Four ~ 7 × 10 ^-2 You may add oxygen on the order of Pa. In addition to oxygen, O _Three , N ₂ , N ₂ O, H ₂ O, NH _Three Etc. can be used according to the purpose.
[0036]
Moreover, in this invention, the partial pressure of the water in the vacuum chamber which forms a transparent conductive film is set to 1.3x10. ^-Four It can be formed by a manufacturing method in which the pressure is set to Pa or less and then an inert gas and oxygen are introduced. The partial pressure of water is more desirably 4 × 10. ^-Five Pa or less, more desirably 2 × 10 ^-Five It can be controlled to Pa or less.
[0037]
In the present invention, in order to adjust the crystal size of the transparent conductive film, water is intentionally added to 1.3 × 10 10. ^-Four ~ 3x10 ^-2 You may introduce in the range of Pa. This adjustment may be performed by introducing water using a variable leak valve or a mass flow controller after forming a vacuum once. Moreover, it can implement also by controlling the back pressure of a vacuum chamber. Basically, it is desirable that no water is present in order to obtain a good quality transparent conductive crystal.
[0038]
When determining the water pressure in the present invention, a differential exhaust type in-process monitor may be used. Alternatively, a quadrupole mass spectrometer having a wide dynamic range and capable of measurement even under a pressure of 0.1 Pa level may be used. In general, 1.3 × 10 ^-Five In a degree of vacuum of about Pa, it is water that forms the pressure. Therefore, the value measured by the vacuum gauge may be considered as the moisture pressure as it is.
[0039]
In the present invention, since a polymer film is used as the substrate, the substrate temperature cannot be raised above the softening point temperature of the polymer film. Therefore, in order to form a transparent conductive film, the temperature of the polymer film needs to be about room temperature or lower to the softening point temperature or lower. In the case of polyethylene terephthalate, which is a typical polymer film, it is desirable to form the conductive film while keeping the substrate temperature at 80 ° C. or lower when no special treatment is performed. More desirably, the substrate temperature is 50 ° C. or lower, and more desirably 20 ° C. or lower. Further, even on a heat-resistant polymer, it can be formed at a substrate temperature set to 80 ° C. or lower, more desirably 50 ° C. or lower, and further desirably 20 ° C. or lower from the viewpoint of controlling outgas from the polymer film. desirable.
[0040]
The transparent conductive laminated body for touch panels of this invention makes the film thickness (d) of a transparent conductive film into 10-30 nm from a viewpoint of color tone and light transmittance. When the film thickness of the transparent conductive film is smaller than 10 nm, the film becomes discontinuous, the resistance value is remarkably increased, and the function as the transparent conductive film is lost. On the other hand, when the film thickness is thicker than 30 nm, the light transmittance starts to decrease significantly, and the function as a touch panel is lost. The film thickness is more preferably in the range of 15 to 25 nm, and further preferably in the range of 18 to 23 nm.
[0041]
The crystal grain size of the transparent conductive film of the present invention is preferably 20 to 1000 nm. The crystal grain size is desirably measured with a transmission electron microscope, but may be determined by observation of the surface with a scanning electron microscope or an approximate equation of Debye-Sherrar from an X-ray diffraction method. When the crystal grain size becomes smaller than 20 nm, the writing durability deteriorates. Conversely, when the crystal grain size exceeds 1000 nm, the crystal grain boundary inside the transparent conductive film decreases rapidly, resulting in an increase in the mobility of the transparent conductive film. This causes a significant decrease in the resistance value, so that the function as a touch panel is lost.
[0042]
The transparent conductive film in the present invention is substantially crystalline, and the reflection intensity from the (222) plane derived from a crystal based on indium oxide (indium oxide crystal) is strongly measured. According to the present invention, the reflection intensity is measured by the concentration method in the X-ray diffraction method, the obtained X-ray diffraction intensity (I) is divided by the film thickness (d), and the measurement is further performed. When the normalized intensity (I / d) / P divided by the X-ray source input power (P) of the diffractometer is 6 to 60 cps / nm / kW, excellent writing durability can be realized. When the normalized strength is less than 6 cps / nm / kW, crystallization is often insufficient and writing durability is deteriorated. When the normalized strength exceeds 60 cps / nm / kW, the crystal grains become too small, and the writing durability deteriorates. In order to improve the writing durability, the range of 10 to 40 cps / nm / kW is particularly desirable.
[0043]
The indium oxide crystal has a bixbite type crystal lattice. The lattice constant of the indium oxide crystal lattice is not changed in the range of tin oxide concentration, which is the composition range of the transparent conductive film in the present invention. In particular, when the X-ray source of the X-ray diffractometer uses CuKα rays, reflection from the (222) plane is given at about 30.5 ° (2θ). X-ray diffraction intensity is measured by a concentration method. In the optical system for X-ray diffraction measurement, X-rays generated from an X-ray source pass through a solar slit that restricts vertical divergence, and then pass through a divergence slit having a width of 1 ° to be irradiated onto a sample The The diffraction line reflected from the sample passes through a scattering slit having a width of 1 °, passes again through a solar slit that restricts divergence in the vertical direction, passes through a light receiving slit at 0.15 °, and is monochromatic. After passing through the meter, it reaches the scintillation counter which is a detector. A 0.45 ° second light receiving slit can be placed in front of the scintillation counter. The widths of the diverging slit, the scattering slit, and the light receiving slit, excluding the solar slit, are desirably the same even when the measuring apparatus is different.
[0044]
As the X-ray source, any one of Co, Fe, Cu, and Ni is used. However, it is desirable to use Cu because the angle at which the diffraction line is observed differs depending on the X-ray source. X Line (Kα line) Is used without being monochromatic.
[0045]
The electric power supplied to the X-ray source depends on the type of tube, but in the case of a rotating counter-cathode, it is desirable to input an electric power of 10 kW (50 kV × 200 mA). In the case of an enclosed tube, it is desirable to apply 1.6 kW (40 kV × 40 mA) power. The applied power is not necessarily required, but the applied voltage is preferably 40 kV or more. If it is smaller than this, the generated characteristic X-ray intensity may not show a proportional relationship with the input power.
[0046]
The film thickness of the sample used for measurement can be determined using a generally used technique. As a typical method, film formation for a certain period of time is performed on a substrate, and an area on the substrate where the film can be peeled off after film formation with an adhesive tape is created in advance. In this method, the film formation rate is obtained by measurement with an atomic force microscope, and the film thickness is calculated from the actual film formation time. Or it can also obtain | require using a fluorescent X ray analysis method or Rutherford backscattering method.
[0047]
【Example】
Examples are shown below, but the present invention is not limited thereto.
[0048]
X-ray diffraction was measured using Rigaku RU300. The X-ray source was a rotating anti-cathode type, and CuKα rays were used without being monochromatic. The input power to the X-ray source was 10 kW (50 kW × 200 mA). X-ray diffraction was measured by a concentration method. The slits were a diverging slit and a scattering slit of 1 ° and a light receiving slit of 0.15 °. A graphite monochromator was installed, and the diffraction line intensity from the (222) plane of the indium oxide crystal was measured with a scintillation counter.
[0049]
For the total light transmittance, Nippon Denshoku 300A was used.
[0050]
The specific resistance was obtained by calculation as a product of film thicknesses measured by a fluorescent X-ray method by measuring the surface resistance using a Mitsubishi Chemical LorestaMP MCP-T350, which is a four-terminal resistance meter.
[0051]
For the crystal grain size, the average crystal grain size was determined from a JEM-2000 transmission electron micrograph made by JEOL.
[0052]
The writing durability was evaluated by observing the appearance after performing 300,000 linear reciprocations using a polyacetal pen with a tip of 0.8 R applied with a load of 250 g.
[0053]
The data of Examples and Comparative Examples are summarized in Table 1.
[0054]
[Example 1]
As the substrate, a polyethylene terephthalate film (OFW manufactured by Teijin DuPont Films) having a thickness of 188 μm was used. A high refractive index layer having a thickness of 50 nm formed by adding a hard coat layer by coating using a 3 μm-thick urethane acrylic UV curable resin on both surfaces of the substrate, and further adding silicon oxide ultrafine particles to tetrabutoxy titanate; An antireflection layer composed of a low refractive index layer having a thickness of 45 nm formed by hydrolyzing alkoxysilane was formed on one surface thereof.
[0055]
After the ultimate vacuum was set to 1.3E-5 Pa or less, oxygen was introduced to 1.3E-2 Pa. There, Ar was introduced as a process gas, and the total pressure was 0.4 Pa. Then, 1 W / cm is applied to the indium oxide sintered target containing 3 wt% tin oxide. ² Electric power was applied at a power density of 20 nm, and a 20 nm transparent conductive film was laminated on the antireflection layer by DC magnetron sputtering. The laminate had a specific resistance immediately after film formation of 1.3E-3 Ω · cm and a total light transmittance of 88%.
[0056]
This laminated body was heat-treated in a 130 ° C. constant temperature bath for 4 hours. As a result, the specific resistance was 1.5E-3 Ω · cm, and the total light transmittance was 89%. The normalized intensity of the X-ray diffraction intensity from the (222) plane of the transparent conductive film was 10 cps / nm / kW. The crystal grain size observed with a transmission electron microscope was about 100 nm. The result of writing durability was good.
[0057]
[Example 2]
Using a polyethylene terephthalate substrate coated with the same coating as in Example 1, the ultimate vacuum was set to 2.7E-4 Pa or less, and oxygen was then introduced into 1.3E-2Pa. There, Ar was introduced as a process gas, and the total pressure was 0.4 Pa. Then, 4 W / cm was applied to the indium oxide sintered target containing 3 wt% tin oxide. ² Electric power was applied at a power density of 20 nm, and a 20 nm transparent conductive film was laminated on the antireflection layer by DC magnetron sputtering. The laminate had a specific resistance immediately after film formation of 1.0E-3 Ω · cm and a total light transmittance of 89%.
[0058]
This laminated body was heat-treated in a 130 ° C. constant temperature bath for 4 hours. As a result, the specific resistance was 1.3E-3 Ω · cm, and the total light transmittance was 90%. The normalized intensity of the X-ray diffraction intensity from the (222) plane of the transparent conductive film was 42 cps / nm / kW. The crystal grain size observed with a transmission electron microscope was about 80 nm. The result of writing durability was good.
[0059]
[Example 3]
Using a polyethylene terephthalate substrate coated with the same coating as in Example 1, the ultimate vacuum was set to 2.7E-4 Pa or less, and oxygen was then introduced into 1.3E-2Pa. There, Ar was introduced as a process gas, and the total pressure was 0.4 Pa. Then, 4 W / cm is applied to the indium oxide sintered target containing 5 wt% tin oxide. ² Electric power was applied at a power density of 20 nm, and a 20 nm transparent conductive film was laminated on the antireflection layer by DC magnetron sputtering. The laminate had a specific resistance immediately after film formation of 1.3E-3 Ω · cm and a total light transmittance of 88%.
[0060]
This laminated body was heat-treated in a 130 ° C. constant temperature bath for 4 hours. As a result, the specific resistance was 1.5E-3 Ω · cm, and the total light transmittance was 89%. The normalized intensity of the X-ray diffraction intensity from the (222) plane of the transparent conductive film was 38 cps / nm / kW. The crystal grain size observed with a transmission electron microscope was about 120 nm. The result of writing durability was good.
[0061]
[Example 4]
As the substrate, polycarbonate having a thickness of 100 μm (Pure Ace manufactured by Teijin) was used. A hard coat layer by coating using a urethane acrylic UV curable resin having a thickness of 3 μm was applied to both sides of the substrate, and an antireflection layer similar to that of Example 1 was formed on one side thereof.
[0062]
After the ultimate vacuum was set to 1.3E-5 Pa or less, oxygen was introduced to 1.3E-2 Pa. There, Ar was introduced as a process gas, and the total pressure was 0.4 Pa. Then, 1 W / cm is applied to the indium oxide sintered target containing 3 wt% tin oxide. ² Electric power was applied at a power density of 20 nm, and a 20 nm transparent conductive film was laminated on the antireflection layer by DC magnetron sputtering. The laminate had a specific resistance immediately after film formation of 1.0E-3 Ω · cm and a total light transmittance of 89%.
[0063]
This laminated body was heat-treated in a 130 ° C. constant temperature bath for 4 hours. As a result, the specific resistance was 1.2E-3 Ω · cm, and the total light transmittance was 90%. The normalized intensity of the X-ray diffraction intensity was 12 cps / nm / kW. The crystal grain size observed with a transmission electron microscope was about 110 nm. The result of writing durability was good.
[0064]
[Example 5]
Using a polycarbonate substrate coated with the same coating as in Example 4, the ultimate vacuum was set to 1.3E-4 Pa or less, and oxygen was introduced to 1.3E-2 Pa. There, Ar was introduced as a process gas, and the total pressure was 0.4 Pa. Then, 4 W / cm is applied to the indium oxide sintered target containing 5 wt% tin oxide. ² A transparent conductive film was laminated to a thickness of 20 nm on a polyethylene terephthalate substrate having a substrate temperature of 5 ° C. by DC magnetron sputtering. The laminate had a specific resistance immediately after film formation of 0.9E-3 Ω · cm and a total light transmittance of 89%.
[0065]
This laminated body was heat-treated in a 130 ° C. constant temperature bath for 4 hours. As a result, the specific resistance was 1.0E-3 Ω · cm, and the total light transmittance was 90%. The normalized intensity of the X-ray diffraction intensity was 25 cps / nm / kW. The crystal grain size observed with a transmission electron microscope was about 90 nm. The result of writing durability was good.
[0066]
[Table 1]

PET: Polyethylene terephthalate
PC: Polycarbonate
Specific resistance 2 and transmittance 2 are values after heat treatment at 130 ° C. for 4 hours.
The unit of specific resistance is Ω · cm, the unit of transmittance is%, the unit of normalized intensity of X-ray diffraction intensity is cps / nm / kW, and the unit of crystal grain size is nm
[0067]
[Example 6]
The X-ray diffraction intensity from the (222) plane of the sample of Example 5 was measured with the input power to the X-ray source being 6.4 kW (40 kV, 160 mA). The normalized intensity of the X-ray diffraction intensity obtained as a result was 21 cps / nm / kW. This indicates that the input power to the X-ray source and the X-ray diffraction intensity from the (222) plane are substantially proportional.
[0068]
[Comparative Example 1]
Using a polyethylene terephthalate substrate coated with the same coating as in Example 1, the ultimate vacuum was set to 1.3E-5 Pa or less, and oxygen was introduced to 3.3E-3 Pa. There, Ar was introduced as a process gas, and the total pressure was 0.4 Pa. Then, 1 W / cm is applied to an indium oxide sintered target containing 5 wt% tin oxide. ² Electric power was applied at a power density of 20 nm, and a 20 nm transparent conductive film was laminated on the antireflection layer by DC magnetron sputtering. The laminate had a specific resistance immediately after film formation of 6.0E-4 Ω · cm and a total light transmittance of 84%.
[0069]
This laminated body was heat-treated in a 130 ° C. constant temperature bath for 4 hours. As a result, the specific resistance was 6.5E-4 Ω · cm, and the total light transmittance was 85%. The normalized intensity of the X-ray diffraction intensity was 5 cps / nm / kW. The crystal grain size observed with a transmission electron microscope was about 1500 nm. As a result of writing durability, the transparent conductive film began to be shaved. Furthermore, the resistance value was too low for touch panel applications.
[0070]
[Comparative Example 2]
Using a polyethylene terephthalate substrate coated with the same coating as in Example 1, the ultimate vacuum was set to 1.3E-5 Pa or less, and oxygen was introduced to 1.3E-2 Pa. There, Ar was introduced as a process gas, and the total pressure was 0.4 Pa. Then, 1 W / cm is applied to the indium oxide sintered target containing 1 wt% tin oxide. ² Electric power was applied at a power density of 20 nm, and a 20 nm transparent conductive film was laminated on the antireflection layer by DC magnetron sputtering. The laminate had a specific resistance immediately after film formation of 2.0E-3 Ω · cm and a total light transmittance of 88%.
[0071]
This laminated body was heat-treated in a 130 ° C. constant temperature bath for 4 hours. As a result, the specific resistance was 2.2E-3 Ω · cm, and the total light transmittance was 88%. The normalized intensity of the X-ray diffraction intensity was 75 cps / nm / kW. The crystal grain size observed with a transmission electron microscope was about 60 nm. Cracks occurred in the transparent conductive laminate. As a result of writing durability, the transparent conductive film began to peel off.
[0072]
[Comparative Example 3]
Using a polyethylene terephthalate substrate coated with the same coating as in Example 1, the ultimate vacuum was set to 6.7E-4 Pa or less, and oxygen was then introduced into 1.3E-2Pa. There, Ar was introduced as a process gas, and the total pressure was 0.4 Pa. Then, 4 W / cm is applied to the indium oxide sintered target containing 5 wt% tin oxide. ² Electric power was applied at a power density of 20 nm, and a 20 nm transparent conductive film was laminated on the antireflection layer by DC magnetron sputtering. The laminate had a specific resistance immediately after film formation of 1.0E-3 Ω · cm and a total light transmittance of 87%.
[0073]
This laminated body was heat-treated in a 130 ° C. constant temperature bath for 4 hours. As a result, the specific resistance was 1.2E-3 Ω · cm, and the total light transmittance was 88%. The normalized intensity of the X-ray diffraction intensity was 3 cps / nm / kW. The crystal grain size observed with a transmission electron microscope was about 60 nm. As a result of writing durability, the transparent conductive film began to peel off.
[0074]
【The invention's effect】
As described above, according to the present invention, standardization One degree and film thickness A transparent conductive laminate in which a transparent conductive film having a predetermined range is formed on a polymer film is extremely useful for a touch panel having good writing durability.

Claims (3)

A transparent conductive laminate for a touch panel in which a transparent conductive film mainly composed of substantially crystalline indium oxide is laminated on at least one surface of a polymer film, and is a (222) plane derived from the crystal of indium oxide The X-ray diffraction intensity is measured by the X-ray diffraction method, and the obtained X-ray diffraction intensity (I) is divided by the film thickness (d) of the transparent conductive film. For a touch panel in which the normalized intensity (I / d) / P divided by the input power (P) of the X-ray source is 6 to 60 cps / nm / kW, and the film thickness of the transparent conductive film is 10 to 30 nm Transparent conductive laminate.
(Here, the X-ray diffraction method is a concentration method, and the X-ray source is any one of Co, Fe, Cu, and Ni, and Kα rays are used without being monochromatized. , Install a light receiving slit slit and use a scintillation counter as a detector.)   The transparent conductive laminated body for touchscreens of Claim 1 in which the said transparent conductive film contains 2-7.5 weight% tin oxide.   The transparent conductive laminated body for touchscreens of Claim 1 or 2 whose crystal grain diameter in the said transparent conductive film is 20-1000 nm.