TW201139730A - Two-layer flexible substrate and process for producing same - Google Patents

Abstract

Provided is a two-layer flexible substrate, in particular, a two-layer flexible substrate suitable for fine-pattern formation or COF mounting, which not only has no pinholes of a thin copper film layer or a copper layer that are due to pinholes generated when an undercoat metal layer was formed on an insulator film by dry plating, but also has few pinholes of the undercoat metal layer, and which has excellent adhesion between the insulator film and the undercoat metal layer and excellent corrosion resistance and water resistance. Also provided is a process for producing the two-layer flexible substrate. The two-layer flexible substrate is obtained by forming an undercoat metal layer by dry plating on at least one surface of an insulator film without through any adhesive and forming a thin copper film layer and/or a copper layer on the undercoat metal layer by dry plating. The insulator film had undergone a surface treatment, and the insulator film after the surface treatment had an oligomer amount that was up to 70% of the oligomer amount of the insulator film which had not undergone the surface treatment.

Description

201139730 VI. Description of the invention: [Technical jaw region to which the invention pertains] The present invention relates to a two-layer flexible substrate and a method of manufacturing the same, and more particularly to forming an underlying metal layer by dry plating on an insulator film (hereinafter sometimes referred to as "seed layer"), and then a two-layer flexible substrate having less pinholes and concave defects when a copper layer is formed, and a method for producing the same. [Prior Art] Today, LCDs, mobile phones, digital cameras, and various types of electrical equipment are required to be thin, compact, and lightweight. The electronic components mounted thereon are oriented toward miniaturization and are used to form substrates for electronic circuits. There are: a rigid printed wiring board with a rigid plate shape, and a flexible printed wiring board (hereinafter sometimes referred to as "FPC") which is flexible and flexible. In particular, the FPC application is used in places such as LCD driver wiring boards, HDD (hard disk drives), DVD (digital versatile optical disk) modules, hinges of mobile phones, and the like. Therefore, its demand will increase. , as a user of the FPC material, a copper-clad laminate in which a copper foil (conductor layer) is adhered to an insulating film such as a polyimide or a polystyrene (hereinafter, the CCL is roughly classified into two types. Insulating film and steel drop (CCL adhered by adhesive (commonly called "3々ccl", 卩 under layer CCL"), another type of insulating film and (4) (conductor layer) are not used = 3 100108894 201139730 In the case of CCL (usually referred to as "two-layer CCL" by means of a washing method, a lamination method, a metallization method, etc., hereinafter, "two layers of c, if the "3 Zan CCL" and "two layers of CCL" In comparison, in terms of manufacturing cost, the three-layer CCL is relatively easy to manufacture in terms of material cost and handling property such as insulation, adhesive, etc., and is inexpensive. On the other hand, heat resistance, thin film formation, and size In terms of stability and other characteristics, the two-layer ccl is excellent, and it is affected by fine patterning and high-density mounting of the circuit. Although it is a high unit price, the demand for a thin two-layer CCL is gradually expanding. The method of installing 1C on the FPC is to form a wiring pattern on the CCL. The COF that detects the light passing through the insulator film at the 1C position is installed as the mainstream, and the thinness of the material itself and the transparency of the insulating material are required. In this regard, it is also advantageous for the two-layer CCL. The manufacturing method of the two-layer CCL can be roughly classified into three types. The first type is a method of adhering an insulating film to an electrolytic steel foil or a rolled copper foil by a casting method, and the second type is laminated on an insulating film. A method of adhering electrolytic copper or rolling copper foil. The third method uses dry plating on an insulating film (here, "dry plating" means sputtering, ion plating, cluster ions A method of forming a copper layer on an insulating film by providing an underlying metal layer of a thin film and a copper layer on the insulating film, usually in the form of a cluster i〇n beam method, a vacuum deposition method, a CVD method, or the like. This method is called “metallization method.” Because the metallization method is free to control the thickness of the metal layer by using dry plating and wet plating (eg, 100108894 201139730 such as electroplating), the metal layer is Thinning, compared to The casting method or the lamination method is relatively easy. Moreover, since the interface between the polyimide and the metal layer has high smoothness, it is generally considered to be suitable for a fine pattern. However, the CCL obtained by the metallization method is metal-insulated. Since the interface between the metal and the insulating film is relatively smooth, the misalignment effect generally used cannot be expected, and the adhesion strength of the interface cannot be sufficiently exhibited. That is, the 2-layer CCL formed by the metallization method is used. If implemented at 121 <^ 95% RH, "Pressure Cooker Test" at a high temperature of 2 atm, high humidity, and high pressure for a long time. Compared with the initial strength of the joint, there is a large bond strength. The tendency to decrease. Therefore, in consideration of drying after application of the liquid photoresist in the pattern forming step, heat of about 100 to 15 ° C is applied to the skin, and is also applied when force is applied to the formed pattern by bonding or the like. The heat of the thief and the wiring are sealed by a sealing resin such as a solder resist to make the 2 bedrooms manufactured by the dense method. ΓΤ... The two-layer CCL made by the metallization method is not suitable for the high temperature synthesis, COF reading, heat conduction, resistance _ ~ or lack of problems. For example, a method for solving such a problem is a method in which a metal alloy layer containing Nl and Cr as a main component in the patent document is used as an insulating thin film case with an acoustic layer (seed layer), but when a finer pattern is formed Further, Patent Document 2 discloses a method in which a copper film composed of copper or an alloy containing copper as a main component is directly provided on at least one surface of a plastic film substrate. A flexible printed circuit board comprising: a surface layer having a crystal structure; and a two-layer structure in which a bottom layer of a polycrystalline structure is provided between the surface layer and the plastic film substrate, and the copper film X In the ray analysis pattern, the peak intensity of the lattice plane index (200) is divided by the peak intensity of the lattice plane index (in). The relative intensity ratio of the X-rays is (2〇〇)/(iil); 1 or less, and the bottom layer is formed by using a plasma containing a mixed gas containing nitrogen to form a functional group on the plastic film substrate to form a metal composed of copper or an alloy containing copper as a main component. The atoms constituting the plastic film substrate are chemically bonded and formed to enhance moisture resistance. However, the invention relies on the control of the lattice surface and the composite effect produced by the plasma treatment to achieve 'but control the lattice surface in the technology. It is difficult to carry out mass production. Further, in order to form a thin film on the insulating film, a vacuum deposition method, a sputtering method, an ion plating method, or the like is generally used, but a film layer obtained by such a dry plating method usually has a majority. A pinhole having a size of several tens of μm to several hundreds of μm, and thus the underlying metal layer tends to have an exposed portion of the insulator film due to the pinhole. Conventionally, in such a flexible wiring board, the thickness of the copper conductive film required for wiring is more than 35 μm and is more than 5 G/mi. However, since the width of the formed wiring is also about several hundred μm, it is very The presence of a small factor of ten pinholes 100108894 6 201139730 causes defects in the wiring section. However, when the flexible wiring board having the narrow-width and narrow-pitch wiring portions which is the object of the present invention is obtained, as described above, it is preferable that the thickness of the copper film for forming the wiring portion is 15 μm or less, preferably 8 μm or less. The ideal thickness of about 5 gm is extremely thin, which increases the possibility of defects in the wiring portion. In this case, the flexible wiring board is manufactured by a subtractive method using a two-layer flexible substrate in which a copper film layer having a desired thickness is formed on an insulating film on which an underlying metal layer is formed. As an example, the formation of the wiring portion pattern is carried out in accordance with the following procedure. (1) A photoresist layer having a desired wiring portion pattern of a copper conductor layer that shields only the wiring portion but exposes the non-wiring portion is provided on the copper conductor layer. (2) The exposed copper conductor layer is subjected to a chemical etching treatment to be removed. (3) Finally, the photoresist layer is peeled off. Therefore, when a substrate having a thickness of 5 μm of an ultra-thin steel film layer is formed, for example, when a wiring width of 15 μm, a wiring pitch of 3 (N), a narrow wiring width, and a narrow wiring pitch wiring board are used, the substrate is subjected to dry plating treatment. The underlying metal layer: the size of the pinholes produced by the reading, the size of the thicker ones will be several tens to hundreds (four): grade, so when forming a new steel film of thickness, the insulator film exposed by the pinhole (4) The sub-portion is almost impossible to be buried. Therefore, the exposed portion (that is, the defective portion of the conductor layer) may be involved in the wiring portion, causing the wiring portion to be defective at the pinhole position and becoming a wiring defect, which may cause the wiring portion to be closely connected. Bad cause. 100108894 7 201139730 Therefore, Patent Document 3 discloses a technique for defining a pinhole of a metal polyimine film laminate. However, Patent Document 3 does not disclose the pinhole of the vapor film and defines the pinhole after the copper plating, and the pinholes of the vapor deposited film and the underlying metal layer are not exposed. Further, as a method for solving the above problem, Patent Document 4 discloses that: a thin metal layer is formed on a thin film by a dry stitching method, and (10) a copper coating layer using electroless woven is further applied as an intermediate metal layer. A method in which the exposed portion of the insulator film caused by the pinhole is covered. However, although this method can surely eliminate the exposed portion of the insulator film due to the pinhole to some extent, it is known that the ore solution and the pretreatment liquid used in the treatment of the electroless copper ray are from A wide variety of pinhole portions of the formed size penetrate between the insulator film and the underlying metal layer. This phenomenon may result in adhesion to the underlying metal layer and subsequent use of the formed conductive copper layer. The inconsistency is not a sufficient solution. Moreover, even if the computer can scream the exposed portion of the insulating film, since the adhesion between the insulating thin layer and the copper layer is low, if the underlying metal layer has pinholes, it will cause the deterioration of the dense material and the insulating property. . [PRIOR ART DOCUMENT] [Patent Document] Patent Document 1: Japanese Patent Laid-Open Publication No. Hei. No. Hei. No. Hei. No. Hei. No. Hei. No. Hei. No. Hei. [Problem to be Solved by the Invention] The object of the present invention is to solve the above problems in the manufacture of a two-layer flexible substrate using a dry plating method, and to provide: The copper foil film layer and the copper layer are damaged due to the pinholes generated when the underlying metal layer is formed by the dry ore treatment on the insulator film, the underlying metal layer is less damaged, and the adhesion between the insulator film and the underlying metal layer is small. The two-layer flexible substrate excellent in corrosion resistance and water resistance is particularly suitable for a two-layer flexible substrate for fine pattern formation and COF mounting, and a method for producing the same. (Means for Solving the Problem) The present inventors have found that the underlying metal layer is formed by dry plating on at least one side of the insulating film without using an adhesive, and the underlying metal layer is formed on the underlying metal layer. A two-layer flexible substrate requiring a thick copper film layer and/or a copper layer, wherein the insulator film is subjected to surface treatment, and the amount of the oligomer is 2 layers of 70% or less of the amount of the oligomer before surface treatment. The flexible substrate can obtain defects in the copper film layer and the copper layer without pinholes generated when the underlying metal layer is formed, and the underlying metal layer is less defective' and between the insulator film and the underlying metal layer The two-layer flexible substrate excellent in adhesion, corrosion resistance, and water resistance can also be applied to a flexible wiring board having a narrow width and a narrow pitch wiring portion, and the present invention has been completed. According to a first aspect of the present invention, a two-layer flexible substrate is formed on a single surface of an insulator film of at least 100108894 9 201139730, and an underlying metal layer is formed by dry plating without passing through an adhesive. The method of forming a copper thin film layer by dry plating, wherein the 'insulating thin film is subjected to surface treatment on at least one side thereof, and only the surface of the insulating thin film is subjected to the surface treatment of the oligomer, and the surface is treated before the surface treatment The amount of the polymer is 70% or less. According to a second aspect of the invention, the copper thin film layer of the first invention has a thickness of 50 nm to 500 nm, and has no pinholes having a diameter exceeding 30 μm, and a pinhole having a diameter of 5/xm or more and 30 μm is 45,000 or less per square meter. According to a third aspect of the present invention, in the two-layer flexible substrate of the first and second aspects of the invention, the copper wet plating layer is formed on the copper thin film layer by wet plating. According to a fourth aspect of the present invention, the copper wet plating layer of the third invention has 0. 5/rni~12μιη thickness, and no concave defects with a diameter or maximum defect length exceeding 2〇/xm, and the direct or maximum defect length lO^rn or more, 20/xm or less concave defect is 2200 or less per 1 square meter . According to a fifth aspect of the present invention, in the two-layer flexible substrate of the first to fourth aspects, the 'underlying metal layer has a layer thickness of 5 nm to 50 nm and contains 6% by weight to 22% by weight of an additive element mainly composed of chromium. The rest is formed of a nickel-chromium alloy composed of nickel, and the layer thickness of the conductor layer (copper layer) composed of the copper thin film layer and the copper wet plating layer provided on the underlying metal layer is shameful. melon. According to a sixth aspect of the invention, the insulator film of the first to fifth inventions is a polyimide film, a polyamide film, a polyester film, a polytetrafluoroethylene film, a polyphenylene sulfide film, or a poly Naphthalene dicarboxylate, film, liquid crystal polymerization 100108894 10 201139730 A resin film selected from the film of the system. According to a seventh aspect of the present invention, in the first to sixth aspects of the invention, the surface treatment is at a pressure of 0. 8Pa~4. In the inert environment of 0 Pa, the surface of the insulator film is subjected to plasma discharge treatment using a DC voltage of 1500 V to 3000 V. According to an eighth aspect of the present invention, in the inert environment of the surface treatment according to the seventh aspect of the invention, the PCT peel strength after the surface treatment is 7 〇〇/ of the initial peel strength. the above. According to a ninth invention of the present invention, the surface treatment of the first to sixth inventions is at a pressure of 0. 8Pa~4. In the inert environment of 0 Pa, the surface of the insulator film was subjected to plasma discharge treatment using a high frequency voltage of 800 V to 2000 V. According to a tenth aspect of the present invention, the surface treatment inert environment of the ninth invention is a nitrogen atmosphere, and the PCT peel strength after the surface treatment is 70% or more of the initial peel strength. According to an eleventh aspect of the present invention, in the at least one surface of the insulating film, the underlying metal layer is formed by dry plating without passing through the adhesive, and the copper thin film layer is formed by dry plating on the underlying metal layer. A method for manufacturing a two-layer flexible substrate, wherein the surface of the insulator film is at a pressure of 0. 8Pa~4. In an inert environment of 0 Pa, a surface metal layer is formed by applying a surface treatment of a plasma discharge between the paired discharge electrodes of the plasma electrode for 2 to 100 seconds. According to a twelfth aspect of the present invention, in the surface treatment by the plasma discharge of the eleventh aspect of the invention, a voltage of 1500 V to 3000 V is applied between the discharge electrodes of the plasma electrode, 100108894 11 201139730. According to a thirteenth aspect of the present invention, in the surface treatment by the plasma discharge of the ηth aspect, a high frequency voltage of 8 〇〇 V to 2000 V is applied between the discharge electrodes of the plasma electrode. According to a fourteenth aspect of the present invention, in the at least one surface of the insulating film, the underlying metal layer is formed by dry plating without passing through the adhesive, and the copper thin film layer is formed by dry plating on the underlying metal layer. The method for producing a two-layer flexible substrate according to the eighth aspect of the invention, wherein the surface of the insulator film is at a pressure of 0. 8Pa~4. In the nitrogen atmosphere of 0 Pa, the surface treatment of the plasma generated by applying a DC voltage of 1500 V to 3000 V between the paired discharge electrodes of the plasma electrode for 2 to 1 Torr is performed to form an underlying metal layer. According to a fifteenth aspect of the present invention, in the at least one surface of the insulating film, the underlying metal layer is formed by dry plating without passing through the adhesive, and the copper thin film layer is formed by dry plating on the underlying metal layer. A method of manufacturing a two-layer flexible substrate according to the first invention, wherein 'the surface of the insulator film is at a pressure of 0. 8Pa~4. In the nitrogen atmosphere of 0 Pa, the surface treatment of the plasma generated by applying a high-frequency voltage of 800 V to 2000 V between the paired discharge electrodes of the plasma electrode for 2 to 1 〇〇 is applied to form an underlying metal layer. According to a sixteenth aspect of the invention, the dry plating method of the eleventh to fifteenth invention is any one of a vacuum deposition method, a sputtering method, and an ion plating method. According to a seventeenth aspect of the present invention, the insulator film of the eleventh to sixteenth aspects of the invention is a polyimide film, a polyamide film, a polyester film, a polytetrafluoroethylene 100108894 12 201139730 film, a polyphenylene sulfide. A resin film selected from the group consisting of a film, a polyethylene naphthalate film, and a liquid crystal polymer film. (Effect of the Invention) According to the present invention, it is possible to obtain a defect in the copper thin film layer and the copper wet plating layer caused by pinholes generated when the underlying metal layer is formed, and the underlying metal layer is less defective, and A two-layer flexible substrate excellent in adhesion between the insulator film and the underlying metal layer and resistance to the button. The two-layer flexible substrate is also suitable for a flexible wiring board having a narrow width and a narrow pitch wiring portion, and thus exhibits an industrially remarkable effect. [Embodiment] 1.  Two-layer flexible substrate The two-layer flexible substrate of the present invention is formed on at least one surface of the insulating film, and when the adhesive is not passed, the underlying metal layer is provided by dry plating, and the underlying metal is provided. A structure in which a copper thin film layer is provided on a layer, wherein the insulating thin film is subjected to surface treatment to make the amount of oligomers less than 70% of the amount of oligomers before surface treatment, by The surface treatment of the insulator film is such that the generation of coarse pinholes can be suppressed as compared with the amount of the oligomer before the surface treatment is '70% or less of the surface amount of the polymer. Furthermore, the two-layer flexible substrate of the present invention preferably has a copper thin film layer having a thickness of 50 nm to 500 nm and has no pinholes having a diameter of 3 μm, and a pinhole per diameter of 5/xm to 30 μm is 1 square inch. 45,000 or less. 100108894 13 201139730 1 -1. Copper film layer The thickness of the copper film layer is preferably 50 nm to 500 nm. The thickness of the copper vl film layer is less than 5Qnm. When the copper wet plating layer is formed on the surface of the steel film layer by the galvanizing steel method which is one of the wet bell coating methods, the resistance of the copper layer is The value will increase and the appearance of the mineral deposit on the surface of the copper layer will deteriorate. Further, when the copper wet plating layer is formed by the electroplating copper method, the copper thin film layer functions as a cathode, and the electric resistance value of the copper thin film layer poses a problem. On the other hand, when the thickness of the copper thin film layer exceeds 5 〇〇 nm and the film is formed, the pinholes between the copper thin films are reduced, but it is time-consuming and economical to form the copper thin film layer by dry plating. Poor. In general, the thicker the copper film layer and the steel wet plating layer are, the more copper can be grown and the pinholes are buried, so that the pinholes are small and even less. Therefore, a two-layer flexible substrate is produced by providing a copper wet plating layer on the surface of the copper thin film layer by a wet deposition method in which the film formation speed is relatively fast. The two-layer flexible substrate has a small number of pinholes on the surface by wet plating. However, even if the pinholes on the surface of the two-layer flexible substrate are buried, the pinholes of the underlying metal layer and the copper thin film layer are not buried. Therefore, when the size and number of pinholes of the underlying metal layer and the copper thin film layer are not suppressed, the wiring portion pattern having a narrow wiring pitch is formed, and the wiring portion without the underlying metal layer is easily exposed, resulting in wiring defects, even if This is not the reason why the wiring part is poorly connected. Furthermore, the pinholes of the 'copper film layer are buried by wet ore. However, if there is a pinhole of the copper film layer of 100108894 14 201139730, the metal layer of the service layer will be exposed to the atmosphere before application. The layer is deteriorated, which causes the wiring to be trapped and the wiring portion to be poorly connected. Therefore, in the copper thin film layer of the present invention, even if it has a pinhole, it is preferably a pinhole having a diameter of 5 divisions to 3 mm. 45 square meters square: Within the range. In addition, the diameter is less than _ $ pinhole because it will lead to wiring defects, poor adhesion, and the detection is also relatively _, so there is no specified quantity. By making the structure of the society, it is possible to obtain the copper (four) defect caused by the pinholes generated when the bamboo has the underlying metal layer, and the underlying metal layer has fewer defects, and the film and the underlying gold are between the film and the underlying gold. A two-layer flexible substrate excellent in adhesion, recording resistance, and water quality. 1-2. Surface treatment of insulator film (substrate) The surface treatment of the insulator film of the substrate was carried out by electroporation. The surface treatment can be applied to one side of the insulator film, but it is more effective for double-sided implementation. The processing conditions are in an inert environment, 0. 8Pa~4. 0Pa pressure. Under pressure is not enough. In the inert environment of milk, the plasma discharge is not easy to find, if the pressure is exceeded. In the inert environment of 〇Pa, since the treatment becomes too strong, there is a case where the insulating film is creased during processing, which is not preferable. A DC voltage of 15 〇〇 v 〜 3 〇〇〇 v was applied between the paired discharge electrodes of the plasma electrode, and DC plasma (DC plasma) treatment was performed. If the DC voltage is less than 100108894 15 201139730 15 and the treatment of the secret electricity is used, the initial adhesion strength cannot be increased. If W_V is exceeded, the treatment will become too strong, so the insulation film is easily caused during the treatment. Wrinkling and deformation occur, which in turn leads to a decrease in heat-resistant adhesion strength and PCT peel strength, which is less preferable. A high frequency voltage of π 8 〇〇 v to 2000 V is applied between the paired discharge electrodes of the electropolymer electrode, and a high frequency M (RF f slurry) treatment is performed. If the high-frequency voltage is less than 800 V, the treatment by the plasma is too weak, and the initial adhesion strength does not rise. If it exceeds 2000 V, the treatment becomes too strong, so that the insulating film tends to occur during the treatment. Wrinkles and deformations are therefore less preferred. In addition, the term "inert atmosphere" means "a gas of Group 18 such as nitrogen or argon", which may be a mixed gas of nitrogen and argon, and the PCT may be stripped if it is subjected to surface treatment by electric ferrolysis in a nitrogen atmosphere. The strength is 70% or more of the initial peel strength. The processing time by plasma discharge is preferably from 2 seconds to 100 seconds. If the treatment time of the plasma discharge is less than 2 seconds, the treatment is too weak, which does not contribute to the increase of the initial adhesion strength. If the treatment is continued for more than 100 seconds, the influence is excessive, and the insulating film is likely to wrinkle and deform. The result is that the heat-resistant adhesion strength and the PCT adhesion strength are lowered, which is less preferable. On the other hand, from the viewpoint of productivity, the longer the treatment time of more than 100 seconds, the more the amount of the insulator film-based oligomer of the β substrate is, the more the pinhole of the copper film layer is increased. 100108894 16 201139730 When the surface treatment of one side of the insulating H film is performed, the 'the amount of the insulator film oligomer after the surface treatment' is preferably 70/〇 or less compared with the amount of the oligomer before the surface treatment. When the surface of the insulator film is subjected to surface treatment on both sides, the amount of the oligomer of the insulator film after the surface treatment is preferably 35% or less compared with the amount of the oligomer before the surface treatment, and the amount of the S polymer is reduced by the surface treatment. The reason is that the oligomer is removed by surface treatment, and the "oligomer" molecule is in the range of $300 to 14000. When the insulator film is produced, it is not sufficiently polymerized and remains. The molecules in the film. The amount of the oligomer was determined by measuring the amount of the oligomer as follows. The oligomer is extracted from the insulator film by using a solvent such as tetrahydroanthracene, and the molecular weight distribution can be measured by size exclusion chromatography (SEC method). 1-3. The underlying metal layer preferably has a layer thickness of 5 nm to 50 nm. If the thickness of the underlying metal layer formed by the nickel-chromium-based alloy mainly composed of chromium as an additive element obtained by the dry plating method is less than 5 nm, the long-term adhesion of the underlying metal layer will still be obtained through the subsequent processing steps. problem appear. In addition, if the thickness of the underlying metal layer is less than 5 nm, the etching solution may be infiltrated during wiring processing, which may cause problems such as floating of the wiring portion, and the wiring peeling strength may be significantly lowered, which is undesirable. On the other hand, if the layer thickness of the underlying metal layer exceeds 5 〇 nm, it is difficult to remove the underlying metal layer when the wiring portion is processed, and there is a three-curvature such as a crack in 100108894 17 201139730. The case where the adhesion strength is lowered is poor, and the thickness of the right layer is thicker than that of the 5 thief, which is still poor because it is difficult to perform silver engraving. The composition of the underlying metal layer is from the viewpoint of heat resistance and durability η 12 ft 〇 / -22 tt% 〇 22 weight = which causes a decrease in heat resistance, and the other aspect 1 chrome ratio exceeds that of the processing of the wiring portion of the field. The underlying metal is difficult and therefore less suitable. n . ^. In addition, in the nickel-chromium alloy, in the case of improving the heat resistance and the silver property, the case where the transition metal element 0 • θ metal layer can be appropriately added in accordance with the purpose of the characteristics can be used. For the flexible substrate, the thickness of the underlying metal layer is preferably 15 nm to 50 nm. Further, the bottom metal layer preferably has a chromium ratio of 4% by weight to 22% by weight, and further has 3 turns of 5 weights. %~40% by weight 'The rest is composed of recorded alloys. The ratio of the network is 4 奋 〇 Λ / Λ, to summer / 〇 ~ 22% by weight, is to prevent the resistance due to thermal deterioration", and the strength of the Qing is significantly reduced If the chromium ratio is less than 4% by weight, then the I-eye addition force α' still does not prevent the miscible strength from being significantly lowered due to thermal degradation, and thus is less preferred. If the chromium ratio is more than 22% by weight, then The etching may be less preferred. Therefore, in the case of chromium, it is more preferably 4 wt/〇15 wt/〇, particularly preferably 5% by weight to 12% by weight. h 4 is to improve the durability and the reliability of the insulation, and the reduction is preferably 5 100108894 201139730% by weight to 40% by weight. If the proportion of molybdenum is less than 5% by weight, the effect of addition is not exhibited, and corrosion resistance and insulation reliability are not improved, which is not preferable. Further, if the proportion of molybdenum exceeds 40% by weight, the heat-resistant peel strength tends to decrease extremely, which is not preferable. Furthermore, in the case of the usual nickel-based alloy target, if the nickel ratio is more than 93% by weight, the dry material itself becomes a ferromagnetic body, and when the film is formed by magnetron plating, film formation is caused. The speed is lowered, and thus it is less preferable, and when the underlying metal layer of the present invention is formed by sputtering, since the composition of the dry material of the sputtering is:: the amount of nickel is 93% by weight or less, and thus even if the magnetic control method is used, At the time of filming, a good film formation rate can still be obtained. Further, in the nickel-chromium-molybdenum alloy, γ can be appropriately added to the purpose of improving heat resistance and corrosion resistance, and a metal element can be added. In addition to the nickel-chromium-molybdenum alloy, in addition to the nickel-chromium-molybdenum-molybdenum alloy, it is possible to have impurities which are less than 5% by weight of the niobium contained in the target material. . In addition, in the formation of the underlying metal layer and the copper thin film layer, the dry plating method is used, and in the dry plating method, it is preferable to use any of the vacuum evaporation method, the sputtering method, or the ion forging method. By. 1_4·Insulator film (substrate) In addition, in the flexible substrate of the present invention, the insulator of the substrate is thin. The film is made of a polyimide film, a polyamide film, or a polyester film. A vinyl film, a polyphenylene sulfide film, and a polyethylene naphthalate system 100108894 19 201139730 A resin film selected from a film or a liquid crystal polymer film. ❹, it is more suitable to use an insulator with a film thickness of 25 to 75 yang. film. In addition, since inorganic materials such as glass fibers are an obstacle to laser processing and chemical etching, it is preferable not to use a substrate containing an inorganic material. 1-5. Copper layer (conductor layer) The two-layer flexible substrate of the present invention is formed on the underlying metal layer by a wet-coating method to form a copper-laid layer, and then a wet-weave is provided on the copper layer by wet bonding. The layer is further laminated to form a copper layer having a thickness of 1 Onm to 12/im including a __ and _ bond bond layer. When the copper layer is formed by only the dry ore method, the dry bell method is a vacuum distillation method, a ship method, or a secret method, and the phase-wet wet reading method also has a slow film formation rate. In the case, it is more suitable for the case of forming a thinner copper layer. On the other hand, after the steel film layer is formed by the dry type II deposition method, the copper layer is formed by wet plating on the copper film layer, which is suitable for forming a thick copper layer in a short time, which contributes to productivity improvement. When the outermost surface of the two-layer flexible substrate of the present invention is a copper thin film layer, the number of pinholes having a diameter of 5 Mm to 30/mi is suppressed to each! 45 square meters or less, if the outermost surface is a copper wet plating layer, the number of concave defects having a diameter or maximum defect length of 10/xm to 20/mi is suppressed to 22 (9) or less per square meter. It is suitable for the manufacture of flexible wiring boards with narrow pitch wiring. 2. Method for Producing Two-Layer Flexible Substrate Hereinafter, a method for producing a two-layer flexible substrate of the present invention will be described in detail with reference to 100108894 20 201139730. * In the present invention, the base material for the base material is a polyaniline (tetra) film, a polystyrene film, a polyester film, a polytetrafluoroethylene film, a polyphenylene sulfide film, a polyphthalate m (4). The insulating film of the resin film selected from the film and the liquid crystal polymer (4) is formed on one or both sides thereof without forming an underlying metal layer, and a copper thin film layer is formed on the underlying metal layer. The insulator film of the substrate usually contains moisture, and it is necessary to perform atmospheric drying or the removal of the moisture present in the body before the formation of the underlying metal layer composed of the chromium-based alloy by the dry forging method. If this action is not; i, the adhesion to the underlying metal layer will be deteriorated. When the underlying metal layer is formed by the dry ore method, for example, when a wire-type metal layer of a wound-type sputtering apparatus of R〇U t〇Roll is used, the target having the underlying metal layer is mounted on the sputtering. On the cathode. First, after performing vacuum evacuation in a sputtering apparatus equipped with an insulator film, nitrogen or argon or a mixed gas of nitrogen and argon is introduced, and the inside of the apparatus is maintained at a pressure of 0. 8Pa~4. In an inert environment of 0 Pa, apply 15 〇〇V~3_v DC voltage or 8〇〇v~2〇〇〇v high-frequency voltage between the paired discharge electrodes of the (four) electrode and finely rotate for 2 seconds~_second. Perform surface treatment. Next, argon gas is introduced, and the inside of the apparatus is held at about 13 Pa, and the winding film in the apparatus and the insulator film which is wound around the front side are conveyed at a speed of about 3 m per minute. The connected lining straight 100108894 201139730 flow power supply to start the sputtering discharge, and the underlying metal layer composed of a nickel-chromium alloy or a chrome-turn alloy is formed on the insulator film. The formation of the copper thin film layer is the same as in the case of the underlying metal layer, and the copper thin film layer is formed by using a sputtering apparatus ‘where the copper target is mounted on the sputtering cathode. At this time, the underlying metal layer and the copper thin film layer are preferably formed continuously in the same vacuum chamber. After the underlying metal layer is formed, the film is taken out in the atmosphere, and when a copper thin film layer is formed by using another sputtering device, the film must be formed. Adequate dehydration was performed beforehand. Further, when the copper thin film layer is formed by the dry bond method and the copper wet plating layer is formed by wet plating on the copper thin film layer, for example, electroless copper plating is preferably performed. In the electroless plating treatment, an electroless copper plating layer is formed on the entire flexible substrate, and even if there is a pinhole, the exposed surface is covered and the entire flexible substrate surface is formed into a good conductor. Thereby, the influence of the pinhole can be suppressed. However, when electroless copper plating is performed, it is necessary to pay attention to the penetration caused by the electroless plating solution and its pretreatment liquid and determine the conditions. In addition, the layer thickness of the copper-plated wet plating layer formed by the electroless copper plating solution is as long as the defects on the repairable substrate surface due to pinholes are applied and the electroplated copper plating solution is applied. The layer thickness which does not dissolve due to the electroplating copper plating solution can be 'better' in the range of Ogm. The substrate on which the electroless copper plating wet plating layer has been formed is formed as a copper wet plating layer capable of forming a final desired layer thickness, and the electroplated copper treatment is performed to obtain a metal layer which is not affected by the underlying metal layer. The two-layer flexible substrate which is affected by the various sizes of pinholes caused by 100108894 22 201139730 is good and has a high degree of adhesion. Further, the electroplating copper treatment performed in the present invention may be carried out by any of the conditions of the electroplating copper method which is carried out by the usual method. Accordingly, the layer thickness of the copper wet plating layer formed on the underlying metal layer and the copper thin film layer is preferably 12 μπ 1 or less. The reason for setting the layer thickness is to obtain a wiring board having a narrow wiring width and a narrow wiring pitch. Further, whether or not the copper wet plating layer is formed by wet plating on the surface of the copper thin film layer is appropriately selected in accordance with the method for producing the wiring portion pattern. For example, when the wiring portion pattern is formed by a known removal method, the wiring portion is formed by the underlying metal layer, the copper thin film layer, and the copper wet plating layer, and thus it is necessary to form a copper wet plating layer. It is required to be the layer thickness required for the wiring portion. Here, the removal is performed by providing a photoresist layer on the surface of the copper layer of the two-layer flexible substrate, and then providing a predetermined line of money on the green skin, and then exposing the material line from above to expose the ' The film is obtained by subjecting an unnecessary steel layer or the like to an engraved mask, then removing the exposed copper layer, and then removing the remaining photoresist layer. The underlying metal layer, which is not required for the wiring portion, is also removed by the money, and the method of forming the wiring portion is fortunate. On the other hand, when the wiring portion pattern is formed by the semi-additive method, the copper wet green layer may be provided on the steel film groove by the wet-wet reading method, or 5 may not be provided. The term "semi-additive method" as used herein refers to a two-layer Nike (iv) metal layer (a metal layer formed from an underlying metal layer and a copper film (4), or a bottom metal layer, steel 100108894 23 201139730 film layer and plate plating). a photoresist layer is disposed on a surface of the metal layer formed by the cladding layer, and a mask having a predetermined wiring pattern is disposed on the photoresist layer, and then ultraviolet rays are irradiated from above to be exposed, and the image is obtained by using the image. On the surface of the metal layer, the electric clock is formed on the surface of the metal layer to form a wiring portion, and the metal layer exposed in the opening portion is used as a cathode, and the photoresist layer is removed by the parent (four)-line portion, and then the soft layer is removed. On the other hand, a method of forming a wiring portion pattern by completing the wiring portion by removing the unnecessary metal layers on the surface of the two flexible substrates other than the wiring portion. [Examples] Hereinafter, the present invention will be described in detail by way of examples, but the invention should not be construed as limited. The measurement of each characteristic was carried out using the means shown below. The method for measuring pinholes is to use a layered body of a bottom metal layer and a copper film layer obtained by a dry method, which is positioned by a penetrating method, and then measured by an optical microscope, and a pinhole having a diameter of one to three 〇 is measured. The number of square meters per square meter. The method for evaluating the amount of oligomers is to extract the plasma-treated insulating film by tetrahydromanganese, and then use the size exclusion chromatography (SEC method) to determine the proportion of oligomers having a molecular weight of 380 to 13500. The value before the electroforming treatment was set to 1 GG%, and a peak was observed and regarded as "amount of oligomer". The method for determining the peel strength is in accordance with IPC-TM-650, NUMBER2. 4. The method of 9 is ^; and is regarded as "initial peel strength". However, the wire width was set to 1 mm, and the peeling angle was set to 9 G. . The wire is formed by removing 100108894 24 201139730, and the soil is placed in a 15GC_ box for (6) hours. After being taken out, it is placed to a 9〇° toughness strength and is considered as “heat-resistant stripping*,,, twinning. The finger beam system will form a thin test box with a thin wire of 1 mm wire in the room temperature, by evaluating the strength and the strength of the fool, and the film substrate of the film of the wire surface is formed at 2 atmospheres ^ When the hot press production was placed at 96], the S was placed until it became a dish, and was evaluated by evaluating the peel strength of 9°°, and was regarded as “PCT peel strength”. The measurement of the Pt3 is performed on the surface of the copper wet recording layer obtained by the electric key method using an optical microscope, and the size of the concave defect is measured. #凹凹 is a circular case, and the number of diameters is 10 to 20 A squares per square inch. § The concave defect is a circle other than a circle, and the maximum length of the defect of the concave defect is regarded as " The maximum defect length", 骇ΙΟμιη to 20/mi concave defects per 1 square meter. (Comparative Example 1) First, Comparative Example 1 shows the characteristics of a two-layer flexible substrate which was formed by performing a film formation without performing a polymerization treatment. The i-th layer of the underlying metal layer is formed on one surface of a 38/mi polyimide film (Kapton 150EN, manufactured by Toray DuPont Co., Ltd.), and the first layer of the underlying metal layer is 20% by weight. I saw the alloy target (manufactured by Sumitomo Metal Mining Co., Ltd.), using DC sputtering method in the Ar environment, depending on the film formation speed. 7nm/sec will be 20% by weight of the 底层 犯 alloy underlying metal layer into a 100108894 25 201139730 film. The layer thickness was measured using a transmission electron microscope (TEM: manufactured by Hitachi, Ltd.) for a part of the film formed under the same conditions, and the result was 0. 02/xm. Further, a second layer was formed on the film by the above-mentioned 20% by weight (> the film was formed on the film, and a Cu target (manufactured by Sumitomo Metal Mining Co., Ltd.) was used for the second layer, and a copper film having a thickness of 10 〇 nm was formed by sputtering. The layer was then formed by copper plating to a thickness of 8/mi. The initial peel strength of the obtained two-layer flexible substrate was 471 N/m, the pCT peel strength was 253 N/m, and the number of pinholes of the dry substrate was 76714. The amount of oligomer was 100%, and sufficient initial peel strength was not obtained. (Example 1) The following is exemplified by the case where the surface treatment by the electric paddle treatment was performed on the insulating film. β The thickness of the polyimide was adjusted to 38 μm. Film (manufactured by Toray DuPont, registered trademark "Kapton 150") under nitrogen pressure i. In a 6 Pa environment, a DC voltage of 2000 V was applied between the paired discharge electrodes of the plasma electrode for 5 sec seconds, and only the film formation surface of the underlying metal layer was subjected to plasma treatment. Next, a first layer of an underlying metal layer is formed on the plasma-treated surface of the polyimide, and the second layer of the underlying metal layer is a 20% by weight Cr-Ni alloy target (Sumitomo Metal Mining Co., Ltd.) System), using the DC sputtering method in the Ar environment, depending on the film formation speed 〇. A 20 μ% Cr-Ni alloy underlayer metal layer was formed into a film at 7 nm/sec. The layer thickness was measured using a transmission electron microscope (TEM: manufactured by Hitachi, Ltd.) for a part of the film formed under the same conditions, and the result was 100-108894 26 201139730, which was 0_02 μm. Further, a second layer was formed on the 20 wt% Ni-Cr film, and the second layer was formed by using a Cu target (manufactured by Sumitomo Metal Mining Co., Ltd.) to form a thickness of the copper thin film layer by sputtering. Then, a film was formed by copper plating to a thickness of 8 μm. The initial peel strength of the obtained two-layer flexible substrate was 624 N/m, the PCT peel strength was 434 N/m, and the dry plating (layered body of the underlying metal layer and the copper thin film layer. Hereinafter referred to as "dry plating") was used. The number of holes was 36,443 / m2, and there were no pinholes with a diameter exceeding 30 μm, the amount of oligomers was 70%, the number of concave defects was 1951/m2', and there were no concave defects with a diameter or a maximum defect length exceeding 2 μm. (Example 2) A 38/mi polyimide film ("Kapton 15" manufactured by Toray DuPont Co., Ltd.) was placed under a nitrogen pressure of 2. In a 4 Pa environment, a DC voltage of 2000 V was applied between the paired discharge electrodes of the electropolymer electrode for 5 sec seconds, and only the film formation surface of the underlying metal layer was subjected to plasma treatment. Then, the first layer of the underlying metal layer is formed on the plasma-treated surface of the polyimide, and the first layer of the underlying metal layer is made of 20% by weight of Cr-Ni alloy dry material (Sumitomo Metal Mining Co., Ltd.) System) 'Using DC sputtering method in Ar environment, according to film formation speed 0. 7 nm/seC A 20 wt% Cr-Ni alloy underlayer metal layer was formed into a film. The thickness of the layer was measured using a transmission electron microscope (TEM: manufactured by Toray Industries, Inc.) in part of the film formation under the same conditions, and the result was 0. 02μιη. A second layer was further formed on the 20% by weight Ni-Cr film, and the second layer was a Cu target (manufactured by Sumitomo Metal Mining Co., Ltd.), and the product was formed by a method of forming a copper thin film layer 100 nm. The thickness was then filmed to a thickness of 8 μm by a copper electric clock method. The initial peel strength of the obtained two-layer flexible substrate was 635 N/m, the PCT peel strength was 463 N/m, the number of pinholes for dry plating was 15,571 / m 2 , and none of the pinholes having a diameter exceeding 30 μm, the amount of oligomer It is 56%, the number of concave defects is 1645/m2' and there are no concave defects with a diameter or a maximum defect length exceeding 20 μm. (Example 3) A 38/rni polyimide film (manufactured by Toray DuPont Co., Ltd., registered trademark "Kapton 150EN") was placed under a nitrogen pressure of 3. In a 1 Pa environment, a DC voltage of 2000 V was applied between the paired discharge electrodes of the plasma electrode for 50 seconds, and only the film formation surface of the underlying metal layer was subjected to plasma treatment. Next, a first layer of the underlying metal layer is formed on the plasma-treated surface of the polyimide, and the first layer of the underlying metal layer is made of 20% by weight of Cr-Ni alloy dry material (Sumitomo Metal Mining Co., Ltd.) System), using the DC sputtering method in the Ar environment, according to the film formation speed of 0. A 20 wt% Cr-Ni alloy underlayer metal layer was formed into a film at 7 nm/sec. The thickness of the layer was measured using a transmission electron microscope (TEM: manufactured by Toray Industries, Inc.), and the result was 0·02 μιη. Further, a second layer was formed on the above-mentioned 20% by weight Cr-Ni film, and the second layer was made of Cu dry material (manufactured by Sumitomo Metal Mining Co., Ltd.), and a thickness of 100 nm of the copper thin film layer was formed by the Tibetan clock method, and then reused. The copper plating method was performed to a thickness of 8 μm.

The initial peel strength of the two-layer removable substrate was 632 N/m, the peel strength of PCT 100108894 28 201139730 was 467 N/m, the number of pinholes for dry plating was 8236/m2, and the diameter of white no more than 30/mi. The pinholes, the amount of oligomers were 5%, the number of concave defects was 2005/m2' and there were no concave defects with a diameter or a maximum defect length exceeding 2 μm. (Comparative Example 2) It is intended to use a 38/xm polyimide film (trademark "Kapton 150EN", manufactured by Toray DuPont Co., Ltd.) under a nitrogen pressure of .7 Pa in a pair of discharge electrodes of a plasma electrode. A 500V DC voltage was applied for 15 seconds, but the discharge was unstable and could not be processed. (Comparative Example 3) A film of 38 μm thick polyimine film (trademark "Kapton 150", manufactured by Toray DuPont Co., Ltd.) was applied at a nitrogen pressure of 4.7 Pa to apply 3500 V DC between the paired discharge electrodes of the plasma electrode. The plasma was treated for 6 seconds at a voltage, but wrinkles appeared on the surface, which prevented subsequent evaluation of the characteristics. (Example 4) The two-layer flexibility of Example 4 was produced in the same manner as in Example 1 except that the argon gas pressure was 3.6 Pa, and the plasma electrode was subjected to a direct current of 2,800 V and a plasma treatment was performed for 6 seconds. Substrate. The initial peel strength of the obtained two-layer flexible substrate was 612 N/m, the number of pinholes of the dry plating was 7,428 / m 2 ', and none of the pinholes having a diameter exceeding 30 / an, the amount of the oligomer was 50%, and the concave defect The number is 889/m2, and there are no concave defects with a diameter or a maximum defect length exceeding 20 μm. (Example 5) 100108894 29 201139730 Two layers of Example 5 were produced in the same manner as in Example 1 except that the argon gas pressure was 1.6 Pa, and a DC of 2,200 V was applied to the plasma electrode and plasma treatment was performed for 6 seconds. Flexible substrate. The initial peel strength of the obtained two-layer flexible substrate was 627 N/m, the number of pinholes of the dry bell was 5142/m2, and none of the needles having a diameter exceeding 30/rni, and the amount of the oligomer was 70%. Further, the measurement of the concave defects of the two-layer flexible substrate of Example 5 was not carried out. (Example 6) The two-layer flexibility of Example 6 was produced in the same manner as in Example 1 except that the argon gas pressure was 3.6 Pa, and the plasma electrode was applied with a direct current of 1600 V and a plasma treatment was performed for 6 seconds. Substrate. The initial peel strength of the obtained two-layer flexible substrate was 626 N/m, the number of pinholes for dry plating was 6428/m2, and there were no pinholes having a diameter exceeding 30 μm, and the amount of the oligomer was 70%. Further, the measurement of the concave defects of the two-layer flexible substrate of Example 6 was not carried out. (Comparative Example 4) Although an argon gas pressure of 0.7 Pa was applied and a direct current of 500 V was applied to the plasma electrode for 6 seconds, the discharge was unstable and processing was impossible. (Comparative Example 5) Although argon gas pressure of 4.7 Pa was applied and a direct current of 3,500 V was applied to the plasma electrode for 6 seconds of plasma treatment, wrinkles appeared on the surface, and subsequent evaluation of characteristics was impossible. 100108894 30 201139730 (Example 7) Except that the mixing gas pressure of 75 vol% argon-25 vol% nitrogen~ is 1.6 Pa, and the plasma electrode is applied with 1800 V DC for 6 seconds, the rest is implemented. Example 1 A two-layer flexible substrate of Example 7 was produced in the same manner. The initial peel strength of the obtained two-layer flexible substrate was 608 N/m, the number of pinholes for dry plating was 8571/m2, and none of the pinholes having a diameter exceeding 30 μm, the amount of oligomers was 70%, and the number of concave defects was 1855 pieces/m2, and all have no concave defects with a diameter or a maximum defect length exceeding 20 μm. (Example 8) The same procedure as in Example 1 except that the mixing gas pressure of 75 vol% argon-25 vol% nitrogen was 1.6 Pa, and the plasma electrode was subjected to a direct current 2300 V and a plasma treatment was performed for 6 seconds. A two-layer flexible substrate of Example 8 was produced. The initial peel strength of the obtained two-layer flexible substrate was 599 N/m, the number of pinholes for dry plating was 7143/m2, and none of the pinholes having a diameter exceeding 30 μm, the amount of oligomers was 50%, and the number of concave defects was 1554 pieces/m2, and all have no concave defects with a diameter or a maximum defect length exceeding 20/xm. (Example 9) The same procedure as in Example 1 except that the mixing gas pressure of 75 vol% argon to 25 vol% nitrogen was 3.6 Pa, and 1500 V DC was applied to the plasma electrode and plasma treatment was performed for 6 seconds. A two-layer flexible substrate of Example 9 was produced. The initial peel strength of the obtained two-layer flexible substrate was 593 N/m, the number of pinholes of the dry plating was 24,000/m2, and none of the needles having a diameter exceeding 3 μm was 100108894 31 201139730, and the amount of the oligomer was 60%. The number of concave defects is 1762 pieces/m2, and there are no concave defects of straight pinching or maximum defect length exceeding 20 μm. (Comparative Example 6) Although a mixing pressure of 75% by volume of argon to 25% by volume of nitrogen was 〇7 Pa, and a DC of 500 V was applied to the plasma electrode for 6 seconds, the discharge was unstable and could not be processed. (Comparative Example 7) Although a mixed gas pressure of 7.5 vol of argon--25 vol% nitrogen was set to 4.7 Pa, and a direct current of 3500 V was applied to the plasma electrode for 6 seconds of plasma treatment, wrinkles appeared on the surface, resulting in subsequent Feature evaluation is not possible. (Example 10) The same procedure as in Example 1 except that the mixed gas pressure of 50 vol% argon-50 vol% nitrogen was 1.6 Pa, and a direct current 3000 V was applied to the plasma electrode and a plasma treatment was performed for 50 seconds. A two-layer flexible substrate of Example 1 was produced. The initial peel strength of the obtained two-layer flexible substrate was 681Ν/Π1, the number of pinholes of dry plating was 18276/m2, and none of the pinholes having a diameter exceeding 30 μm, the amount of oligomers was 70%, and the number of concave defects was 2076 pieces/m2, and all have no concave defects with a diameter or a maximum defect length exceeding 20 μm. (Example 11) The same procedure as in Example 1 except that the mixing gas pressure of 50 vol% argon _50 vol% nitrogen was 1.6 Pa, and the plasma electrode was applied with a direct current of 1800 V and a plasma treatment for 6 seconds. A two-layer flexible substrate of Example 11 was produced. 100108894 32 201139730 The initial separation strength of the obtained two-layer flexible substrate is 572 N/m, the number of pinholes for dry ore is 15286/m2, and there are no pinholes with a diameter exceeding qingm, and the amount of oligomers is 30%. 'The number of concave defects is 1,861/claw 2, and there are no concave defects with a diameter or a maximum defect length exceeding 20 μm. (Example 12) A argon-50 volume was set to 50% by volume. /. A two-layer flexible substrate of Example 12 was produced in the same manner as in Example 1 except that the nitrogen gas was mixed at a pressure of 3 6 Pa and a DC voltage of 2000 V was applied to the plasma electrode for 6 seconds. The initial peel strength of the obtained two-layer flexible substrate was 583 N/m, the number of pinholes of the dry plating was 21,286 / m 2 , and none of the pinholes having a diameter exceeding 3 〇 / im, the amount of the oligomer was 40%, concave The number of defects is 1889/m2, and there are no concave defects with a diameter or a maximum defect length exceeding 20/mi. (Comparative Example 8) Although a mixed gas pressure of 7 vol of 50 vol% argon-50 vol% nitrogen was used, and a direct current of 500 V was applied to the plasma electrode for 6 seconds, the discharge was unstable and could not be processed. : (Comparative Example 9): Although a mixing pressure of 4.7 Pa of 50% by volume of argon-50% by volume of nitrogen was applied, and a DC of 3500 V was applied to the plasma electrode for 6 seconds, the surface was wrinkled, resulting in wrinkles on the surface. Subsequent feature evaluations cannot be performed. (Example 13) Except that the mixing gas pressure of 25% by volume of argon-75 vol% nitrogen was 1.6 Pa, and DC voltage of 1600 V was applied to the 100108894 33 201139730 plasma electrode, and plasma treatment was performed for 6 seconds, A two-layer flexible substrate of Example 13 was produced in the same manner. The initial peel strength of the obtained two-layer flexible substrate was 586 N/m, the number of pinholes for dry plating was 8,857/m2, and none of the pinholes having a diameter exceeding 30 μm, the amount of oligomers was 55%, and the number of concave defects was There are 1428 pieces/m2, and there are no concave defects with a diameter or a maximum defect length exceeding 20 μm. (Example 14) The same procedure as in Example 1 except that the mixing gas pressure of 25% by volume of argon-75 vol% nitrogen was 1.6 Pa, and the plasma electrode was applied with a direct current of 1800 V and a plasma treatment for 6 seconds. A two-layer flexible substrate of Example 14 was produced. The initial peel strength of the obtained two-layer flexible substrate was 567 N/m, the number of pinholes for dry plating was 11,569/m2, and none of the pinholes having a diameter exceeding 30/rni, the amount of the oligomer was 50%, and the concave defect The number is 1276/m2, and there are no concave defects with a diameter or a maximum defect length exceeding 20 μm. (Example 15) The same procedure as in Example 1 except that the mixing gas pressure of 5% by volume of argon-75 vol% nitrogen was 3.6 Pa, and the plasma electrode was applied with a direct current of 2000 V for 6 seconds. A two-layer flexible substrate of Example 15 was produced. The initial peel strength of the obtained two-layer flexible substrate was 584 N/m, the number of pinholes of the dry plating was 22,429 / m 2 , and none of the pinholes having a diameter exceeding 30/rni, the amount of the oligomer was 70%, and the concave defect The number is 1987/m2, and there are no concave defects with a diameter or a maximum defect length exceeding 20/ζη. 100108894 34 201139730 (Comparative Example 10) Although the mixing pressure of 25% by volume of argon-75 vol% nitrogen was 〇7 Pa, and the direct current of 500 V was applied to the plasma electrode for 6 seconds, the discharge was unstable and could not be performed. deal with. (Comparative Example 11) Although a mixed gas pressure of 7.5 vol of argon-75 vol% nitrogen was set to 4.7 Pa, and a direct current of 3500 V was applied to the plasma electrode for 6 seconds of plasma treatment, wrinkles appeared on the surface, resulting in subsequent Feature evaluation is not possible. (Example 16) The same procedure as in Example 1 except that the mixing gas pressure of 25% by volume of argon-75 vol% nitrogen was 1.6 Pa, and a high frequency of 600 V was applied to the plasma electrode and plasma treatment was performed for 12 seconds. A two-layer flexible substrate of Example 16 was produced. The initial peel strength of the obtained two-layer flexible substrate was 598 N/m 'the number of pinholes of the dry plating was 9847/m2, and none of the pinholes having a diameter exceeding 30 μm, the amount of the oligomer was 65%, and the number of concave defects was 1564 pieces/m2, and all have no concave defects with a diameter or a maximum defect length exceeding 20/mi. (Example Π) The same as Example 1 except that the mixing gas pressure of 25% by volume of argon-75 vol% nitrogen was 1.6 Pa, and a high frequency of 1000 V was applied to the plasma electrode and a Π second plasma treatment was performed. A two-layer flexible substrate of Example 17 was produced. The initial peel strength of the obtained two-layer exchangeable substrate was 608 N/m, the number of pinholes for dry plating was 15098/m2′, and none of the needles having a diameter exceeding 30 μm 100108894 35 201139730, the amount of oligomers was 63%, concave The number of defects is 2〇17/m2, and there are no concave defects with a diameter or a maximum defect length exceeding 20 μm. (Example 18) A volume of 25% by volume of argon-75 was used. /. A two-layer flexible substrate of Example 18 was produced in the same manner as in Example 1 except that the mixed gas pressure of nitrogen was 2.4 Pa, and a high-frequency 600 V was applied to the electropolymer electrode to carry out a plasma treatment for 12 seconds. The initial peel strength of the obtained two-layer flexible substrate was 6i4 N/m, the number of pinholes for dry plating was 19,713/m2', and the pinhole 'oligomer amount system having a diameter exceeding 3 〇μη was 70%, concave defect The number is 1798/m2, and there are no concave defects with a diameter or a maximum defect length exceeding 20 μm. (Comparative Example 12) The mixing gas pressure of 25% by volume of argon-75 vol% nitrogen was 0 3 Pa, and the high frequency of 600 V was applied to the plasma electrode for 12 seconds, but the discharge was unstable and could not be processed. (Comparative Example 13) Although the mixing gas pressure of 5% by volume of argon-75 vol% was 4.7 Pa, and the high frequency of 600 V was applied to the electrode of the electric field, and the electric wave was applied for 12 seconds: treatment, but the surface appeared to be enemies' This will prevent subsequent feature evaluations from proceeding. (Example 19) Example 19 was produced in the same manner as in Example 1 except that the argon gas pressure was 1.6 Pa' and the high frequency 6 〇〇v was applied to the plasma electrode and the plasma treatment was performed for 12 seconds. Layer flexible substrate. 100108894 36 201139730 The initial peel strength of the obtained two-layer flexible substrate is 598 N/m, the number of pinholes for dry plating is 25673/m2, and there are no pinholes with a diameter exceeding 30 μm, and the amount of oligomer is 56%. The number of defects is 1897/m2, and there are no concave defects with a diameter or a maximum defect length exceeding 20/im. (Example 20) The same procedure as in Example 1 except that the mixing gas pressure of 75 vol% argon-25 vol% nitrogen was 1.6 Pa, and the plasma electrode was subjected to a high frequency of 600 V and a plasma treatment was performed for 12 seconds. A two-layer flexible substrate of Example 20 was produced. The initial peel strength of the obtained two-layer flexible substrate was 587 N/m, the number of pinholes for dry plating was 19,476/m2, and none of the pinholes having a diameter exceeding 30 μm, the amount of the polymer was 66%, and the number of concave defects was 1674 pieces/m2, and none have concave defects with a diameter or a maximum defect length exceeding 20/mi. (Example 21) The same procedure as in Example 1 except that the mixed gas pressure of 50% by volume of argon-50% by volume of nitrogen was 1.6 Pa, and a high frequency of 600 V was applied to the plasma electrode and plasma treatment was performed for 12 seconds. A two-layer flexible substrate of Example 21 was produced. The initial peel strength of the obtained two-layer flexible substrate was 569 N/m, the number of pinholes for dry plating was 24,384 / m 2 ', and none of the pinholes having a diameter exceeding 30 μm, the amount of oligomers was 62%, and the number of concave defects was 1720 / m2, and no concave defects with a diameter or maximum defect length exceeding 20 / mi. (Example 22) Example 22 was produced in the same manner as in Example 1 except that a nitrogen gas pressure of 1.6 Pa was applied, and a high frequency of 600 V was applied to the plasma electrode, and 100108894 37 201139730 for 12 seconds of plasma treatment was applied. 2 layers of flexible substrate. The initial peel strength of the obtained two-layer flexible substrate was 601 N/m, the number of pinholes of the dry plating was 27,846/m2, and none of the pinholes having a diameter exceeding 30/rni, the amount of the oligomer was 59%, and the concave defect The number is 2008/m2, and there are no concave defects with a diameter or a maximum defect length exceeding. The results of the above examples and comparative examples are shown in Table 1. 100108894 38 20 ο 3 97 3 Bucket 1<〕 3 fli S Γ〇§ 1 K- 柘€ wt.l 铋W 0 00 5 κ 佥vi ml B? m 00 fH V*) S 卜r*H κ- Μ vi fw.l Bv w l_ o § a 00 % H- Sweatshirt t V? (bJ R) 0 00 CM 2 rs oo ow ff dhI pBr € s? 鲧rpBT El S 1 t> oo σ\ r- 1 1 w: mill £^tD W\ j 1 1 1 1 1 ! 1 1 1 1 1 1 1 Break ί! vi mt 8? 00 v〇R 00 1 w < shouting iDHg3j 11^ (4giJ Ο ο Ο Ο 8 tn g 8 8 o , 0 1 0 1 oo 0 1 0 1 〇»r! <Τ) 0 1 oojo in v〇〇o CO VO ooo: Ol 1 1 o V〇OS 1 o 〇\ dry Single-sided needle of woven substrate?_μ数[/m2] 3; ν〇2 Π \T) ώ 00 00 § s 00 ~1 O 8 o cs 00 g ?! os rs 00 00 O\ v〇— 〇\ &lt ;N CN 卜ON 00 g ro σ\ Ρ·Η . ~~1 1 Pi s〇' «1 1 VO »—1. A os f5 After the first touch CT 〇P !〇?! o 0\ CO CN (N i〇S in w-) !n ~iu^l 1 *〇00 »r> PCT [N/m] CN s δ IT) 00 cs !2 cs 00 (S ~·1 § CN s ΓΛ om ~1 U ^) 〇\ (N sm cn —1 (N ro u·) cn 卜 CN cn 00 On CN s CO s Paste II Os 00 00 « ο s cs cs g § ΓΛ rn rn m S rs 00 σ\ 00 00 cn 〇to v〇ml〇00 ro s〇? S gm initial [N/m] _ 5 Ό 2 CN s rs oo 'O s 00 sa <n $ rj E S3 vo 00 δ s oo On <n 00 s inch w 0 00 〇\ ^T) ss iTi $ \ns The more ti i ΐ ? ί 1 II μ: 〇〇__ 00 00 __ 00 oo 00 00 u. 00 L 00 oo 00 00 00 00 00 00 00 00 00 L 00 00 L_ 00 1 L IOO 00 1 L Dry key bond, copper film layer [nm] ο Ο — or·^ o rH ooo B o O ogoo ο oor·^ I—ooo !〇iH 0 j 1 _ 1 'O 1 underlying metal layer S ο S 〇S ogd (N § CNJ P oososo 1 gd — (NP osdsos 〇sdodsdgdsosd 1 iS 1° [_ gd 11 (4) li 1 沄1 Ό 1 Ο Ό Ό 1 Γ <〇沄卜r° o 1 VD SO 1 v〇CN cs r4 i cs cs is 1 1 (N 8 8 8 S 8 00 pi o CN 8 ο 8 CO 8 22 8 SI ο ΚΓϊ 8 8 s 22 g ο vTi 8 in m IBHIHIIII I just mi 1 1 UP a 卜 UQ 8 δ SS a H δ δ δ δ S -1 gas pressure [Pa] 1 vq 〇 co co 'O CO inch · VO NO CO 卜ο Bu O so rn Bu Ο Bu· ^«4 sD r〇卜d卜寸· v〇NO s 卜寸· \q ρ·Η \D vq mixing ratio 1 1 〇O 8 o ^H 〇° o ° ο ° ~~ ~ in jn JO JQ JO LO 卜 jO r ° o L 1 Ο ooo 〇oo a o »»H ο f—^ s Γ |〇*n LO jn O t: s CS o Gas type _ truJ Bv ml Βν ΓΗ.Ι Ε» 1 _. 1 ΙΛ I l % 1 i〇 1 1 0 1 1 ί 1 S? 〇% g 1 if , Ar-75%N2 i , 1 JO i 1 m L_ 1 I SIS 1 1 1 1 III lil s£55 1 BESSIE] 1 ill I5S5 ι^ί § - $0 .. 6ε [%οΛ]υί : Γ sil 201139730 It is known from Table 1 that the amount of oligomer of the insulator film can be made by subjecting the insulator film to the surface treatment of the plasma treatment according to the conditions specified in the present invention. 70% or less of the amount of the oligomer before the surface treatment, and the number of pinholes of the dry plating can be suppressed to 45,000 pieces/m2 or less, and the number of concave defects of the copper wet plating layer can be suppressed to 2,200 pieces/m2 or less. . Further, when the environmental pressure of the surface-treated plasma treatment was less than 0.8 Pa, it was confirmed that the discharge was unstable, and the surface treatment of the insulator film could not be performed. Further, it has been found that if the applied voltage of the plasma electrode is too high, wrinkles of the insulator film occur, and it is impossible to manufacture a two-layer flexible substrate. 100108894 40

Claims (1)

201139730 VII. Patent application scope: 1. A two-layer flexible substrate is formed on at least one side of an insulator film, and the underlying metal layer is formed by dry ore deposition without passing through an adhesive, and the underlying metal is formed. Forming a copper thin film layer by dry plating on the layer; wherein: the insulating thin film is subjected to surface treatment on at least one side thereof, and only the amount of the oligomer after the surface treatment is performed on one side of the insulating thin film The amount of the oligomer before the surface treatment is 70% or less. 2. The two-layer flexible substrate according to claim 1, wherein the copper thin film layer has a thickness of 50 nm to 500 nm, and each has no pinhole having a diameter exceeding 30 μm, and a pinhole system having a diameter of 5 μm or more and 30 μm 45,000 or less per 1 square meter. 3. The two-layer flexible substrate according to claim 1 or 2, wherein the copper thin film layer is formed by wet plating on the copper thin film layer. 4. The two-layer flexible substrate according to claim 3, wherein the copper wet bond layer has a thickness of μ.5μηι 1212μηη, and has no diameter or most; a large defect length exceeding 20^m The concave defect has a direct or maximum defect length of 10 μm; and the above concave defect of 20 μm or less is 2,200 or less per 1 square meter. 5. The two-layer flexible substrate according to any one of claims 1 to 4, wherein the underlying metal layer has a layer thickness of 5 nm to 5 Å, and is composed of a chromium-containing additive element 6 a weight-% to 22% by weight and the remainder is formed of a nickel-chromium alloy composed of nickel, and a conductor layer composed of a copper thin film layer and a copper wet plating layer of 100108894 201139730 is provided on the underlying metal layer. The layer thickness of the (copper layer) is 50 nm to 12/im. 6. The two-layer flexible substrate according to any one of claims 1 to 5, wherein the insulator film is a polyimide film, a polyamide film, a polyester film, or a polytetra A resin film selected from the group consisting of a vinyl fluoride film, a polyphenylene sulfide film, a polyethylene naphthalate film, and a liquid crystal polymer film. 7. The two-layer flexible substrate according to any one of claims 1 to 6, wherein the surface treatment is performed by using 1500 V on the surface of the insulator film under an inert atmosphere of a pressure of 0.8 Pa to 4.0 Pa. Plasma discharge treatment of ~3000V DC voltage. 8. The two-layer flexible substrate according to claim 7, wherein the surface-treated inert environment is a nitrogen atmosphere, and the PCT peel strength after the surface treatment is 70% or more of the initial peel strength. 9. The two-layer flexible substrate of any one of claims 1 to 6 wherein the surface treatment is performed under an inert atmosphere of a pressure of 0.8 Pa to 4.0 Pa, and the surface of the above-mentioned insulator film is subjected to 800 V. ~2000V high frequency voltage plasma discharge treatment. 10. The two-layer flexible substrate according to claim 9, wherein the surface-treated inert environment is a nitrogen atmosphere, and the PCT peel strength after the surface treatment is 70% or more of the initial peel strength. 11. A method for manufacturing a two-layer flexible substrate, wherein the insulating film is on a single surface of 100108894 42 201139730, and the underlying metal layer is formed by dry plating without passing through an adhesive, and the underlying metal is A copper thin film layer is formed by a dry plating method on a layer, wherein the surface of the insulating film is applied under an inert atmosphere of a pressure of 88 Pa to 4.0 Pa by applying a pair of discharge electrodes to the plasma electrode. After 1 〇〇 of the surface treatment of the plasma discharge, an underlying metal layer is formed. 12. The method of producing a two-layer flexible substrate according to claim 11, wherein the surface treatment by the plasma discharge applies a direct current voltage of 1500 V to 3000 V between the discharge electrodes of the plasma electrode. 13. The method of producing a two-layer flexible substrate according to claim 11, wherein the surface treatment by the plasma discharge applies a high-frequency voltage of 800 V to 2000 V between the discharge electrodes of the plasma electrode. A method for producing a two-layer flexible substrate, which is a method for producing a two-layer flexible substrate according to item 8 of the patent application, in which at least one surface of the insulating film is used without using an adhesive. The dry plating method forms a bottom layer of greedy layer, and a copper film layer is formed by dry plating on the underlying metal layer, wherein the surface of the insulator film is at a pressure of 88 Pa to 4.0 Pa. The lower layer is formed by surface treatment of a plasma generated by applying a 1500 V to 3000 V DC voltage between the paired discharge electrodes of the plasma electrode for 2 to 100 seconds. A method for producing a two-layer flexible substrate, which is a method for producing a two-layer flexible substrate according to claim 100108894 43 201139730, which is based on at least one surface of the insulator film and not via an adhesive. In the case where the underlying metal layer is formed by dry plating, and a copper thin film layer is formed by dry plating on the underlying metal layer, the surface of the insulating film is at a pressure of 0.8 Pa to 4.0 Pa. In the environment, the surface treatment of the plasma generated by applying a high-frequency voltage of 800 V to 2000 V between the paired discharge electrodes of the plasma electrode for 2 to 100 seconds is performed to form an underlying metal layer. The method for producing a two-layer flexible substrate according to any one of claims 11 to 15, wherein the dry plating method is a vacuum vapor deposition method, a sputtering time method, and an ion forging method. Either. The method for producing a two-layer flexible substrate according to any one of claims 11 to 16, wherein the insulator film is a polyimide film, a polyamide film, or a polyester film. A resin film selected from the group consisting of a polytetrafluoroethylene film, a polyphenylene sulfide film, a polyethylene naphthalate film, and a liquid crystal polymer film. 100108894 44 201139730 IV. Designated representative map: (1) The representative representative of the case is: No (2) The symbol of the symbol of the representative figure is simple: No. 5. If there is a chemical formula in this case, please disclose the chemical formula that best shows the characteristics of the invention: Patent Document 4: Japanese Patent Laid-Open No. PCT No. 195668, SUMMARY OF THE INVENTION The object of the present invention is to solve the problem of manufacturing a two-layer flexible substrate using a dry plating method. The above problems are also provided: there is no defect of the copper foil film layer and the copper layer caused by pinholes generated when the underlying metal layer is formed by dry plating on the insulator film, and the underlying metal layer has less defects. The two-layer flexible substrate which is excellent in adhesion between the insulator film and the underlying metal layer, and has excellent recording durability and water quality is particularly suitable for a two-layer flexible substrate which is formed by fine pattern formation and C〇f mounting, and its manufacture. method. (Means for Solving the Problem) The present inventors have found that the underlying metal layer is formed by dry plating on at least one side of the insulating film without using an adhesive, and the underlying metal layer is formed on the underlying metal layer. A two-layer flexible substrate requiring a thick copper film layer and/or a copper layer, wherein the insulator thin layer is subjected to surface treatment, and the amount of the polymer is 7% or less of the amount of the oligomer before the surface treatment. The two-layer holding substrate can obtain the copper film layer and the copper layer defect caused by the two needles generated when the underlying metal layer is formed, and the underlying metal layer has less defects 2, and the insulator film and the bottom layer The two-layer flexible substrate excellent in adhesion between the metal layers, the rhythm resistance, and the water repellency can be obtained from a flexible wiring board having a narrow-width two-pitch wiring portion, and the present invention has been completed. X narrow The invention is the first! The invention is a two-layer flexible substrate which is formed on the single surface of the insulator film at least 100108894 9 201139730 JUL 1 8 2011, and the page 2 layer is not replaced by the adhesive agent ^ ___ 1 , and is processed in the wire gold work. Forming a copper film layer, wherein the insulator film is subjected to a surface treatment on at least the surface thereof, and only the surface of the insulator film is subjected to the surface treatment of the oligomer 罝, which is 70% of the amount of the oligomer before the surface treatment. the following. In the second invention of the present invention, the steel thin film layer of the first invention has a thickness of 50 to 500 nm and has no pinholes having a diameter exceeding 3, and a pinhole having a diameter of 5 μm or more and 30 μm or less is 45 or less per square meter of square meter. . According to a third aspect of the invention, in the two-layer flexible substrate of the first and second aspects of the invention, the _-type plating layer is formed on the copper thin film layer by wet plating. According to a fourth aspect of the present invention, the copper wet plating layer of the third invention has a thickness of 0.5 μm to 12 μm, and has no concave defects having a diameter or a maximum defect length exceeding 2 μm, and the direct or maximum defects are longer than 1 〇 pm. The concave defect of 2 〇 gm or less is 2,200 or less per 1 square meter. According to a fifth aspect of the present invention, in the second aspect of the invention, the second layer flexible substrate has a layer thickness of 5 nm to 50 nm and contains 6% by weight to 22% of an additive element mainly composed of chromium. % and the rest is formed by a nickel-chromium alloy composed of the recording, and the layer thickness of the conductor layer (copper layer) composed of the copper thin film layer and the copper wet plating layer provided on the underlying metal layer 50nm~12μιη. According to a sixth aspect of the invention, the insulator film of the first to fifth inventions is a polyimide film, a polyamide film, a polyester film, a polytetrafluoroethylene film, a polyphenylene sulfide film, or a poly Naphthalene diacetate film, liquid crystal polymerization 100108894 10 201139730 1UL 1 8 2 811 Round Shijing Shiyan Supplement Seven, application for patents 1. A two-layer flexible substrate, at least on one side of the insulator film, Forming a bottom metal layer by dry plating without using an adhesive, and forming a copper thin film layer by dry plating on the underlying metal layer; wherein the insulator film is applied to at least one of the layers The surface treatment is carried out, and only the surface of the above-mentioned insulator thin layer is subjected to the above-mentioned surface treatment, and the amount of the oligomer is 70% or less of the amount of the oligomer before the surface treatment. 2. The two-layer flexible substrate according to claim 1, wherein the copper thin film layer has a thickness of 50 nm to 500 nm, and each has no pinhole having a diameter exceeding 30 μm, and has a diameter of 5 μm or more and 3 μm or less. The pinhole system is 45,000 or less per 1 square meter. 3. The two-layer flexible substrate according to claim 1 or 2, wherein the copper wet plating layer is formed on the copper thin film layer by wet plating. C) The two-layer flexible substrate according to claim 3, wherein the copper wet plating layer has a thickness of 〇·5 μm to 12 μm, and has no concave defects having a diameter or a maximum defect length exceeding 20 μm. And the direct or maximum defect length ι〇μηη or more, and the concave defect of 2〇μηι or less is 2,200 or less per 1 square meter. 5. The two-layer flexible substrate according to any one of claims 1 to 4, wherein the underlying metal layer has a layer thickness of 5 nm to 50 nm and contains 6% by weight of an additive element mainly composed of chromium. ～22% by weight and the remainder is formed of a nickel-based alloy, and a conductor layer composed of a copper thin film layer and a copper wet plating layer is provided on the underlying metal layer (100108894 41 201139730) The layer thickness of the copper layer is 50 nm to 12 μm. 6. The two-layer removable substrate according to any one of the claims 1-5 to the above, wherein the insulator film is from a polyimide film, a polyamide film, a polyester film, a poly 4 A resin film selected from the group consisting of a vinyl fluoride film, a polyphenylene sulfide film, a methyl ketone film, and a liquid crystal polymer film. 7. The two-layer flexible substrate according to any one of claims 1 to 6, wherein the surface treatment is performed by using the surface of the insulator film under an inert atmosphere of a pressure of 8 Pa to 4 〇Pa. Plasma discharge treatment of 1500V~3〇〇〇V DC voltage. 8. The two-layer flexible substrate according to claim 7, wherein the surface-treated inert environment is a nitrogen atmosphere, and the pCT peel strength after the surface treatment is 70% or more of the initial peel strength. 9. The two-layer flexible substrate of any one of claims 1 to 6 wherein the surface treatment is performed under an inert atmosphere of a pressure of 88 Pa to 4.0 Pa. Plasma discharge treatment of 800V~2000V high frequency voltage. A two-layer flexible substrate according to claim 9, wherein the surface-treated inert environment is a nitrogen atmosphere, and the PCT peel strength after the surface treatment is 70% or more of the initial peel strength. η· A method for producing a two-layer flexible substrate ′ is based on an insulator film to 100108894 42 201139730 °°, without using an adhesive, forming a θθ by dry plating, and using a dry type on the underlying metal layer The method of forming a copper thin film layer by a plating method is characterized in that the surface of the ..., 邑, 彖 薄膜 薄膜 在 在 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的 的After 2~1 sec of surface treatment of the plasma discharge, an underlying metal layer is formed. I2. The method for producing a two-layer flexible substrate according to claim 11, wherein the surface treatment by the plasma discharge applies a direct current voltage of 1500 V to 3000 V between the discharge electrodes of the plasma electrode. A method of producing a two-layer flexible substrate according to the seventh aspect of the patent, wherein the surface treatment by plasma discharge applies a high-frequency voltage of 800 V to 2000 V between discharge electrodes of the plasma electrode. A method for producing a two-layer flexible substrate, which is a method for producing a two-layer flexible substrate according to the eighth aspect of the patent application, in which the insulator film is on at least one side of the insulating film without using an adhesive. Forming a bottom metal layer by dry plating, and forming a copper film layer by dry plating on the underlying metal layer, wherein the surface of the insulator film is under a pressure of 〇8 Pa to 4.0 Pa. Next, an underlying metal layer is formed by applying an electrical surface generated by applying a direct current voltage of 1500 V to 3000 V between the paired discharge electrodes of the plasma electrode for 2 to 100 seconds. A method for producing a two-layer flexible substrate, which is a method for producing a two-layer flexible substrate according to claim 100108894 43 201139730, which is based on at least one surface of the insulator film and not via an adhesive. In the case where the underlying metal layer is formed by dry plating, and the copper thin film layer is formed by dry plating on the underlying metal layer, the surface of the insulating film is at a pressure of 88 Pa to 4.0 Pa. Under the nitrogen atmosphere, the surface treatment of the plasma generated by applying a high-frequency voltage of 800 V to 2000 V between the paired discharge electrodes of the plasma electrode for 2 to 100 seconds is performed to form an underlying metal layer. The method for producing a two-layer flexible substrate according to any one of claims 11 to 15, wherein the dry plating method is a vacuum evaporation method, a sputtering method, and an ion ore coating method. Either. The method for producing a two-layer flexible substrate according to any one of claims 11 to 16, wherein the insulator film is a polyimide film, a polyamide film, or a polyester film. A resin film selected from the group consisting of a polytetrafluoroethylene film, a polyphenylene sulfide film, a polyethylene naphthalate film, and a liquid crystal polymer film. 100108894 44