JP2007099970A - Method for modifying surface of base polymer material and the base polymer material the surface of which is modified by using the method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for finely modifying a surface in higher precision by selectively (partially) modifying a part of the surface of a base polymer material. <P>SOLUTION: The method for modifying the surface of the base polymer material is to use a super critical fluid and modify a predetermined area of the surface of the base polymer material by forming a masking layer having an open port with a predetermined pattern on the base polymer material, bringing the super critical fluid containing a dissolved material to contact with the surface of the masking layer of the base polymer material and bringing the material to penetrate into the base polymer material through the open port of the masking layer. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a polymer substrate surface modification method and a polymer substrate surface-modified using the method, and more particularly, to a polymer substrate surface modification method and method using a supercritical fluid. Relates to a polymer substrate surface-modified using

  In recent years, various processes have been proposed in which a supercritical fluid that has permeability as a gas and at the same time functions as a solvent such as a liquid is used for molding a polymer substrate. For example, the supercritical fluid acts as a plasticizer by penetrating into the thermoplastic resin and can reduce the viscosity of the polymer. Therefore, the fluidity of the polymer at the time of injection molding is utilized by utilizing the action of this supercritical fluid. And a method for improving transferability has been proposed (see, for example, Patent Document 1).

  In addition, various methods for enhancing the function such as improving the wettability of the surface of the polymer substrate by utilizing the function of the supercritical fluid as a solvent have been proposed (see, for example, Patent Documents 2 and 3). ). Patent Document 2 discloses that a fiber surface is hydrophilized by dissolving a polyalkyl glycol in a supercritical fluid and bringing the polyalkyl glycol into contact with the fiber. Patent Document 3 discloses a highly functional surface of a polymer substrate that performs dyeing by contacting a supercritical fluid in which a solute as a functional material is dissolved in advance in a supercritical state, that is, under a high pressure, and the polymer substrate. A batch process for disclosing is disclosed.

  Conventionally, a mask having a hole having a desired shape is provided on the substrate, and a supercritical fluid in which a substance (metal complex) to be deposited on the substrate is dissolved is sprayed from above the mask, and the deposited substance is applied to the substrate surface. A method of forming a pattern of 100 μm or less is also proposed (see, for example, Patent Document 4).

Japanese Patent Laid-Open No. 10-128783 JP 2001-226874 A JP 2002-129464 A JP 2002-313750 A

  The above Patent Documents 1 to 3 disclose a method for modifying the surface of a polymer substrate using a supercritical fluid as a solvent, and discloses a technique for modifying the entire surface of the polymer substrate. However, it is difficult to selectively and finely modify a part of the polymer substrate surface by the techniques disclosed in Patent Documents 1 to 3 described above.

  On the other hand, Reference 4 discloses a method in which a substance is partially attached to a selected region of a substrate surface using a supercritical fluid. In this method, a process for manufacturing a mask separately from a substrate is disclosed. There is a problem that the cost is high. Further, in the method disclosed in the cited document 4, only a mask is arranged on the base, so that a gap is formed between the mask and the base, and a supercritical fluid enters the gap and is provided on the mask. In accordance with the shape of the holes, it may be difficult to form the desired pattern by attaching the substance to the substrate.

  The present invention has been made to solve the above problems, and an object of the present invention is a method for selectively (partially) surface-modifying a part of the surface of a polymer substrate. The object is to provide a method for surface modification with high accuracy and fineness.

  According to a first aspect of the present invention, there is provided a method for modifying a surface of a polymer substrate using a supercritical fluid, wherein a mask layer having an opening with a predetermined pattern is formed on the polymer substrate. And a surface including contacting a supercritical fluid containing a substance with the surface of the polymer base on the mask layer side so that the substance penetrates the polymer base through the opening of the mask layer. A reforming method is provided.

  The present applicant has previously proposed a technique for modifying a polymer substrate surface by applying an organic substance to the surface of the polymer substrate in advance and bringing the supercritical fluid into contact with the polymer substrate surface (patent application). 2004-129235). In this application, the following method has been proposed as a method for selectively modifying a part of the surface of the polymer substrate. First, an organic substance intended to permeate the polymer substrate is applied to the entire surface or a wide area of the surface of the polymer substrate, and then a mold surface having a predetermined uneven pattern is brought into close contact with the surface of the polymer substrate. Next, the supercritical fluid flows into the space defined between the mold (concave portion) and the polymer substrate surface, and the applied organic substance is applied only to the region of the polymer substrate surface into which the supercritical fluid has flowed. Selectively penetrate. Therefore, another object of the present invention is to use a mold having a fine concavo-convex pattern formed as in the method of selectively modifying a part of the polymer substrate surface proposed in Japanese Patent Application No. 2004-129235. And providing a method for selectively (partially) modifying a part of the surface of the polymer substrate by a simpler method.

  An example of the surface modification method according to the first aspect of the present invention will be briefly described with reference to FIG. First, the mask layer 3 is formed on the prepared polymer substrate 1. At this time, as shown in FIG. 3A, the mask layer 3 is formed in a region other than the region 4 to be surface-modified on the polymer substrate 1. That is, the mask layer 3 in which the region 4 to be surface-modified on the polymer substrate 1 is an opening is formed. Next, as shown in FIG. 3 (b), a supercritical fluid (SCF: Supercritical Fluid) 5 containing the substance 2 is brought into contact from the mask layer 3 side of the polymer substrate 1. At this time, since the surface of the polymer substrate 1 is exposed at the opening of the mask layer 3, the material contained in the supercritical fluid is exposed to the opening of the mask layer 3 together with the supercritical fluid. It penetrates from the surface of 1 into its interior. As a result, as shown in FIG. 3 (c), the substance 2 penetrates only into the surface region 4 of the polymer substrate 1 exposed at the opening of the mask layer 3. Next, when the mask layer 3 is removed, as shown in FIG. 3 (d), the substance 2 penetrates only into a predetermined region 4 on the polymer substrate 1 to obtain a polymer substrate 10 whose surface is modified.

  In addition, although the example of FIG. 3 has shown the example which all the substance 2 osmose | permeated the polymer base material 1, a part of substance 2 may remain | survive without permeating. The permeation amount of the substance 2 can be arbitrarily controlled by changing conditions such as the temperature, pressure, contact time, substance content (dissolution amount) of the supercritical fluid 5 containing (dissolved) the substance 2. It is preferable to adjust the permeation amount of the substance 2 by appropriately adjusting these conditions according to the application.

  According to the second aspect of the present invention, there is provided a method for modifying a surface of a polymer substrate using a supercritical fluid, wherein a mask layer having an opening with a predetermined pattern is formed on the polymer substrate. Forming a layer of material at least in the opening of the mask layer; contacting the material layer with a supercritical fluid; and penetrating the material into the polymer substrate through the opening of the mask layer And a surface modification method is provided.

  An example of the surface modification method according to the second aspect of the present invention will be briefly described with reference to FIG. First, the mask layer 44 is formed on the prepared polymer substrate 41. At this time, as shown in FIG. 9A, a mask layer 44 is formed in a region other than the region 42 to be surface-modified on the polymer base material 41. That is, the mask layer 44 is formed in which the region 42 to be surface-modified on the polymer base material 41 becomes an opening. Next, a layer 45 of material is formed on the mask layer 44. At this time, as shown in FIG. 9B, not only the region 42 of the polymer substrate 41 exposed at the opening of the mask layer 44 but also the region 45 of the material on the region other than the opening of the mask layer 44. Formed. Note that the present invention is not limited to this, and the material layer 45 may be formed at least in the opening of the mask layer 44, and the material layer 45 is not formed on the region other than the opening of the mask layer 44. May be.

  Next, the supercritical fluid 46 is brought into contact from the material layer 45 side of the polymer base material 41 (state shown in FIG. 9B). At this time, a part of the material layer 45 formed on the region 42 of the polymer base material 41 exposed in the opening of the mask layer 44 (the region 42 to be surface-modified on the polymer base material 41) is supercritical fluid 46. At the same time, it penetrates from the region 42 on the surface of the polymer substrate 41 into the inside thereof. As a result, as shown in FIG. 9 (c), the substance 43 penetrates only into the region 42 on the surface of the polymer base material 41. Next, the organic substance that has not penetrated into the polymer base material 41 is removed (state shown in FIG. 9D). Finally, when the mask layer 44 is removed, as shown in FIG. 9E, the substance 43 selectively penetrates only into the predetermined region 42 on the polymer substrate 41, and the surface-modified polymer substrate 40 is formed. can get.

  In the surface modification method of the present invention, various resins can be used as the polymer substrate. For example, polymethyl methacrylate, polycarbonate, polyamide, polyetherimide, polyamideimide, polyester, polyacetal, polymethylpentene, amorphous polyolefin, polytetrafluoroethylene, liquid crystal polymer, styrenic resin, polymethylpentene, polyacetal, polylactic acid And various thermoplastic resins such as those obtained by mixing these with complex species, polymer alloys containing these as main components, and those obtained by blending these with various fillers.

  In the surface modification method of the present invention, various substances can be used as the supercritical fluid, and in particular, supercritical carbon dioxide (hereinafter also referred to as supercritical carbon dioxide) or supercritical nitrogen. Is preferably used. In particular, supercritical carbon dioxide is most suitable as a plasticizer for thermoplastic resin materials since it has a proven record in injection molding and extrusion molding. Further, air, water, butane, pentane, methanol or the like in a supercritical state may be used as the supercritical fluid. Any fluid that dissolves a substance to some extent can be used. In order to improve the solubility of the substance in the supercritical fluid, the supercritical fluid may be mixed with an entrainer, that is, an alcohol such as acetone, methanol, ethanol, or propanol as an auxiliary agent.

  In the polymer surface modification method of the present invention, the pressure of the supercritical fluid is controlled while the supercritical fluid is in contact with the surface of the polymer substrate (for example, the state of FIG. 3B). It is preferable to press the surface of the polymer substrate with a supercritical fluid at an appropriate pressure. This pressing allows the material to penetrate deeper into the polymer substrate. Further, as described above, the supercritical fluid acts as a plasticizer on the polymer substrate and softens the surface of the polymer substrate. Therefore, when the supercritical fluid is brought into contact with the surface of the polymer substrate or after that, when the surface of the polymer substrate is pressed with a mold or the like, the material is efficiently introduced into the polymer substrate while suppressing deformation of the polymer substrate. Since it can be infiltrated, it is possible to form a more precise pattern on the polymer surface.

  In the surface modification method of the present invention, the conditions such as the temperature and pressure of the supercritical fluid to be brought into contact with the polymer substrate are arbitrary. For example, the threshold value for reaching the supercritical state is a temperature of about 31 ° C. and a pressure of about 7 MPa. When supercritical carbon dioxide as described above is used, the temperature of supercritical carbon dioxide is preferably in the range of 35 to 150 ° C., and the pressure is preferably in the range of 10 to 25 MPa. If the temperature or pressure is outside the above ranges, the solubility of the organic substance in the supercritical fluid and the permeability to the polymer substrate will be insufficient.

  As described above, in the surface modification method of the present invention, the material is infiltrated with the supercritical fluid when the material is selectively infiltrated into the polymer substrate in a predetermined pattern. Therefore, it is preferable to use a substance that is easily dissolved in the supercritical fluid. In the present invention, as the substance that penetrates the surface of the polymer substrate called “substance”, various organic materials (organic substances) as well as inorganic materials modified with organic compounds can be used. Any material can be used as long as it dissolves to some extent in the supercritical fluid. Various materials can be used depending on the purpose and application. For example, as an inorganic material serving as a base of an organic substance, for example, metal alkoxide and the like can be given. Specific examples of substances that can be used in the surface modification method of the present invention and effects thereof will be described below.

  For the purpose of hydrophilizing the surface of the polymer substrate, organic substances such as polyethylene glycol, polypropylene glycol, and polyalkyl glycol can be used as the substance. In particular, since polyethylene glycol dissolves in, for example, supercritical carbon dioxide, it can be easily penetrated into the polymer substrate, and since it has a hydrophilic group (OH), a polymer substrate having a hydrophilic surface can be obtained. Therefore, it is preferable. In addition, a polymer base material hydrophilized using polyethylene glycol having excellent biocompatibility is suitable as a base material used in biochips, μ-TAS (micro total analysis system), and the like. For example, by hydrophilizing the surface of a polymer substrate, which is a hydrophobic material, the effect of controlling the adhesion of nucleic acids and proteins, and the hydrophobization rate of nucleic acids due to the separation in the micro-region of hydrophilization-hydrophobization on the polymer substrate surface It becomes possible to perform separation by.

  When an organometallic complex is used as the substance, a catalyst core for electroless plating can be formed on the polymer substrate. In this case, a plating layer can be formed by electroless plating in the region to which the substance is added.

  As the substance, for example, an azo dye or the like, an organic dye material such as a fluorescent dye or phthalocyanine may be used. When such a material is used as a substance, the surface of the polymer substrate can be dyed.

  As the substance, a hydrophobic ultraviolet stabilizer such as benzophenone or coumarin may be used. When such a material is used as a substance, the tensile strength after weathering of the polymer substrate can be improved.

  As the substance, a fluorinated compound such as a fluorinated organocopper complex may be used. When such a material is used as a substance, it is possible to improve the frictional property of the polymer base material or to have a water repellent function.

  Silicon oil may be used as the substance. In this case, a water repellent function is exhibited on the polymer substrate.

  Furthermore, a material that does not dissolve in the supercritical fluid can be used as the substance. When a substance that does not dissolve in the supercritical fluid is used, when the supercritical fluid is brought into contact with the surface of the polymer substrate, the substance added (applied) to the polymer substrate surface is caused by the pressure of the supercritical fluid. Penetrates into the polymer substrate. In this case, any material can be used as the substance, but it is desirable to use a material having a molecular weight of 5000 or less in consideration of the molecular size of the substance that can easily penetrate into the polymer substrate. However, when an inorganic material such as metal fine particles, nanocarbons such as carbon nanotubes, fullerenes, and nanohorns, titanium oxide, or the like is used as a substance, it is desirable to perform solubilization treatment in a supercritical fluid by chemical modification and physical modification.

  In the surface modification method according to the first and second aspects of the present invention, the mask layer is preferably formed of a polymer material. In the surface modification method of the present invention, any material can be used as long as the mask layer can shield the supercritical fluid and can adhere / adhere to the surface of the polymer substrate. By forming the mask layer with a material having such properties, it is possible to prevent the supercritical fluid from entering the region of the polymer substrate to which the mask layer is adhered / adhered. As a material for forming the mask layer, for example, a photosensitive resin, a thermoplastic resin, a resin dissolved in a volatile solvent, and the like are preferable.

  In the surface modification method according to the first and second aspects of the present invention, the mask layer is preferably formed by a printing method. In the surface modification method of the present invention, as a method for forming the mask layer, any method can be used as long as it is a method capable of forming a mask layer having an opening in a region to be surface-modified of the polymer substrate. In particular, by adhering a liquid mask member such as a photosensitive resin (for example, a photoresist) to a region other than the region where the surface of the polymer substrate is to be modified by a printing method such as a screen printing method or an ink jet method, and curing it. It is preferable to form a mask layer. As another method for forming the mask layer, a photosensitive resin is applied to the entire surface of the polymer substrate, and then the photosensitive region in the region to be surface-modified on the polymer substrate using a metal mask or a photolithography method is used. It is also possible to form the mask layer by removing the functional resin.

  In the surface modification method according to the first and second aspects of the present invention, the method further includes preparing a polymer substrate having a recess formed on the surface of the polymer substrate corresponding to the opening of the mask layer. It is preferable.

  An example of a surface modification method using a polymer substrate in which a recess is formed in a region of the polymer substrate corresponding to the opening of the mask layer (region to be surface-modified) will be briefly described with reference to FIG. explain. First, as shown in FIG. 6A, a polymer substrate 51 in which a region to be surface-modified of the polymer substrate 51 is formed with a recess 52 is prepared. Next, a mask layer 54 is formed on the prepared polymer substrate 51. At this time, as shown in FIG. 6B, a mask layer 54 is formed in a region other than the recess 52 of the polymer substrate 51. That is, the mask layer 54 is formed so that the recess 52 of the polymer base material 51 is exposed in the opening of the mask layer 54. Next, as shown in FIG. 6C, the supercritical fluid 55 containing the substance 53 is brought into contact with the polymer substrate 51 from the mask layer 54 side. At this time, in the recess 52 of the polymer base 51 exposed at the opening of the mask layer 54, the substance 53 contained in the supercritical fluid 55 penetrates into the inside of the polymer base 51 from the surface together with the supercritical fluid. As a result, as shown in FIG. 6 (d), the substance 53 penetrates only into the recess 52 on the surface of the polymer substrate 51. Next, when the mask layer 54 is removed, as shown in FIG. 6E, the substance 53 penetrates only into the recesses formed on the polymer substrate 51, and the polymer substrate 50 whose surface is modified is obtained.

  As described above, when the region to be surface-modified on the polymer substrate is formed with a recess, the recess can serve as a guide when forming a pattern of a substance on the polymer substrate. Moreover, you may form the area | region which should be surface-modified on a polymer base material by a convex part. Furthermore, the pattern of the substance formed on the polymer substrate is used in combination with the pattern of the substance formed on the flat part of the polymer substrate as shown in FIG. 3 as well as the recesses and / or protrusions. Also good. In this case, the function of various patterns can be exhibited more effectively.

  Moreover, when a substance is added to the surface of a flat polymer substrate by a printing method such as a screen printing method or an ink jet method, it is technically difficult to form a fine pattern of 100 μm or less at present. In addition, when a substance is added to a flat polymer substrate surface, if a supercritical fluid is brought into contact with the polymer substrate surface, it may be difficult to form a fine pattern due to bleeding of the pattern of the substance. However, in the surface modification method shown in FIG. 6, for example, a concavo-convex pattern having a width or depth of 100 μm or less, more desirably 50 μm or less, and even more desirably 10 μm or less is formed on the surface of the polymer substrate. When a mask material is added to the region of the polymer substrate other than, for example, by an ink jet method, the accuracy of the opening of the mask layer can be controlled by the accuracy of the shape of the concavo-convex pattern formed on the polymer substrate. Therefore, in the surface modification method as shown in FIG. 6, it is possible to modify the surface by penetrating a substance with a very fine and highly accurate pattern on the polymer substrate.

  In addition, when the surface modification method of the present invention as shown in FIG. 6 is applied to, for example, a device for controlling a liquid such as a biochip or μTAS, specifically, a fine pattern such as a hydrophilic channel. It is effective when forming on a polymer substrate. For example, when a concave groove is formed on a polymer substrate and an organic substance is added to the groove to make it hydrophilic, a liquid such as a specimen or a reagent is produced along the groove due to capillary action acting on the concave groove. Has the effect of making it easier to flow.

  Furthermore, the surface modification method of the present invention as shown in FIG. 6 is also effective when a wiring pattern such as an electric circuit is formed on a polymer substrate. When forming a wiring pattern on a polymer substrate, first, a metal complex is used as a substance, and the substance is added to the wiring pattern portion of the polymer substrate to form a pattern of plating nuclei. Thereafter, a metal pattern is deposited along the pattern of the plating nucleus by an electroless plating method or the like to form a wiring pattern. When a wiring pattern is formed on a polymer substrate as described above, a concavo-convex pattern corresponding to the wiring pattern to be formed in advance is formed on the polymer substrate, and the pattern of the metal complex is formed in the concave portion or convex portion. When formed, the concavo-convex portion serves as a guide during electroless plating to control metal deposition, and a wiring pattern can be formed without increasing the wiring width.

  According to a third aspect of the present invention, there is provided a polymer substrate that has been surface modified using the surface modification method according to the first or second aspect.

  According to the surface modification method for a polymer substrate of the present invention, the mask layer in which the region to be surface modified on the polymer substrate becomes an opening is formed on the polymer substrate in close contact with each other. Even if the supercritical carbon dioxide in which the substance is dissolved is contacted from the mask layer side of the mask layer, the supercritical carbon dioxide in which the substance is dissolved does not enter between the mask layer and the polymer substrate. The surface of the polymer substrate can be modified with a pattern.

  According to the surface modification method for a polymer substrate of the present invention, a mask layer in which a predetermined region to be surface modified on the polymer substrate is an opening is formed on the polymer substrate by a printing method in advance. A substance can penetrate into the polymer substrate with a supercritical fluid through the opening, and a predetermined region on the polymer substrate can be selectively surface-modified. Therefore, in the surface modification method of the present invention, a predetermined region of the polymer substrate surface can be partially surface-modified without using a mold having a fine concavo-convex pattern. Therefore, it is not necessary to individually manufacture molds according to the pattern of the region to be surface-modified, and the cost can be reduced and the process can be simplified.

  Examples of the method for modifying the surface of a polymer substrate of the present invention will be specifically described below with reference to the drawings. However, the present invention is not limited thereto.

  In Example 1, as shown in FIG. 1, a method for surface modification by allowing a dye 2 (substance) to permeate the surface of a polymer substrate 1 (polymer substrate) with a character pattern (“A” and “B”). explain.

[High pressure equipment]
First, a high-pressure apparatus used for infiltrating the dye 2 into the polymer substrate 1 by the surface modification method of Example 1 will be described with reference to FIG. FIG. 2 is a schematic configuration diagram of the high-pressure apparatus 100 used in the surface modification method of this example. As shown in FIG. 2, the high-pressure device 100 mainly includes a high-pressure vessel 11, a CO ₂ cylinder 12, a supercritical fluid adjustment device 13, and pipes 16 a and 16 b that connect these components. .

  As shown in FIG. 2, the high-pressure vessel 11 includes a container body 33 having a recess 31 formed on the surface and a lid 34, and an O-ring 32 is provided on the upper surface of the outer wall of the recess 31 of the container body 33. Yes. In the high pressure container 11 shown in FIG. 2, the lid 34 is placed on the upper surface of the container main body 33 on the concave side and bolted to seal the concave portion 31 of the container main body 33. Further, as shown in FIG. 2, the high-pressure vessel 11 is formed with a flow path 36 and an introduction port 35 that are in communication with the recess 31 of the vessel body 33. Further, as shown in FIG. 2, the flow path 36 circulates with a pipe 16 b through which an external supercritical fluid flows through the inlet 35, and the supercritical fluid generated outside the high-pressure vessel 11 is piped. It is efficiently introduced into the recessed portion 31 of the sealed container body 33 from 16 b through the inlet 35 and the flow path 36. At this time, since the concave portion 31 of the container body 33 is sealed by the lid 34 via the O-ring 32, the supercritical fluid introduced into the concave portion 31 via the introduction port 35 and the flow path 36 is retained in the high pressure vessel 11. There is no leakage to the outside.

As shown in FIG. 2, the supercritical fluid adjusting device 13 mainly includes a booster pump 21, a buffer tank 17, and a substance dissolving tank 18. The CO ₂ cylinder 12 and the supercritical fluid adjustment device 13 are connected by a pipe 16a, and the CO ₂ gas introduced from the CO ₂ cylinder 12 through the pipe 16a into the supercritical fluid adjustment device 13 is supplied by a booster pump 21. And introduced into the buffer tank 17. The introduced CO ₂ gas is boosted to a predetermined pressure in the buffer tank 17 and is adjusted to a predetermined temperature by a heater 17 a provided in the buffer tank 17 (supercritical CO ₂ gas in a supercritical state). Carbon). Then, the supercritical carbon dioxide generated in the buffer tank 17 is introduced into the substance dissolving tank 18, and the substance (in this example, a dye) is dissolved in the supercritical carbon dioxide. Then, the supercritical carbon dioxide in which the substance (in this example, the dye) is dissolved passes through the pipe 16b whose temperature is adjusted to a predetermined temperature by the temperature control device 14, and passes through the flow path 36 from the inlet 35 of the high-pressure vessel 11. It is introduced into the recessed portion 31 that is sealed through.

[Method for surface modification of polymer substrate]
Next, a method for modifying the surface by infiltrating the dye 2 into a predetermined pattern portion (alphabet pattern portion) on the polymer substrate 1 in this example will be described with reference to FIG.

  First, a polymer substrate 1 having a flat surface was prepared. A polycarbonate resin having a glass transition temperature Tg of about 130 ° C. was used for the polymer substrate 1.

  Next, as shown in FIG. 3A, a mask layer 3 was formed in a region on the polymer substrate 1 other than the region 4 to be surface-modified (regions corresponding to alphabets “A” and “B”). That is, the mask layer 3 was formed so that the region 4 to be surface-modified on the polymer substrate 1 was exposed in the opening of the mask layer 3. In this example, a photosensitive resin (manufactured by Kayaku Microchem Co., Ltd., SU-8) was used as the mask layer 3, and the coating thickness of the photosensitive resin was 100 nm. Specifically, the mask layer 3 was formed as follows. First, a photosensitive resin was attached to the surface of the polymer substrate 1 in a region other than the region 4 to be surface-modified on the polymer substrate 1 by screen printing. Next, the polymer substrate 1 to which the photosensitive resin was adhered was dried at 70 ° C. for 1 hour and further cooled at room temperature for 1 hour. Next, the photosensitive resin was irradiated with ultraviolet rays and cured to form a mask layer 3.

  Next, the polymer substrate 1 on which the mask layer 3 was formed was mounted in the high-pressure vessel 11 of the high-pressure apparatus 100 of FIG. Next, as shown in FIG. 3B, the supercritical carbon dioxide 5 in which the dye 2 was dissolved was brought into contact with the surface of the polymer substrate 1 on the mask layer 3 side. In this example, an alcohol (10 wt%) solution of the dye Blue35 represented by the following chemical formula was used as a pigment dissolved in supercritical carbon dioxide.

  Here, as shown in FIG. 3B, the procedure for bringing the supercritical carbon dioxide 5 in which the dye 2 is dissolved into contact with the surface of the polymer substrate 1 on the mask layer 3 side will be described more specifically with reference to FIGS. To do.

First, the polymer substrate 1 on which the mask layer 3 was formed was placed on the bottom of the recess 31 of the high-pressure vessel 11. Thereafter, the recess 34 in the high-pressure vessel 11 was sealed by placing the lid 34 on the vessel body 33 and tightening the bolt. Next, the supercritical fluid was introduced into the recess 31 in the high-pressure vessel 11 as follows. First, the CO ₂ gas cylinder 12 CO ₂ gas through the booster pump 21 of the supercritical fluid regulator 13 is introduced into the buffer tank 17. The introduced CO ₂ gas is pressurized and heated in the buffer tank 17 to generate supercritical CO ₂ (supercritical carbon dioxide). In this example, supercritical carbon dioxide having a temperature of 40 ° C. and a pressure of 15 MPa was generated. Next, the supercritical carbon dioxide generated in the buffer tank 17 is introduced into the substance dissolving tank 18. The dye 2 that dissolves in supercritical carbon dioxide is held in the substance dissolving tank 18, and the dye 2 is dissolved in supercritical carbon dioxide when the supercritical carbon dioxide passes through the substance dissolving tank 18. Next, the valve 15 b is opened, and supercritical carbon dioxide in which the dye 2 adjusted to a predetermined pressure in the supercritical fluid adjusting device 13 is dissolved is introduced into the high pressure vessel via the inlet 35 and the flow path 36 of the high pressure vessel 11. It was introduced into and retained in the sealed recess 31 in the container 11 (state shown in FIG. 3B).

  The piping 16b that connects the supercritical fluid adjustment device 13 and the high-pressure vessel 11 is temperature-controlled to a predetermined temperature by a temperature adjustment device 14 (for example, a temperature adjustment device of a hot water circulation type), so the adjustment temperature of the piping Accordingly, the temperature of the supercritical carbon dioxide passing through the pipe 16b can be adjusted. Therefore, the temperature control device 14 can also adjust the temperature in the recess 31 of the high-pressure vessel 11 into which supercritical carbon dioxide has been introduced. The temperature and pressure in the high-pressure vessel 11 change as the temperature of the supercritical fluid is adjusted, but the temperature and pressure conditions of the supercritical fluid in this embodiment are the same as those before the introduction of the high-pressure vessel 11. It is shown.

  When the supercritical carbon dioxide 5 in which the dye 2 introduced into the recess 31 of the high-pressure vessel 11 is dissolved contacts the surface of the polymer substrate 1 on the mask layer 3 side, the surface of the polymer substrate 1 exposed at the opening of the mask layer 3 Only in region 4 dye 2 penetrates with supercritical carbon dioxide.

  Next, the release valve 24 in the supercritical fluid adjusting device 13 is opened to open the concave portion 31 in the high-pressure vessel 11 to the atmosphere, and then the polymer substrate 1 is taken out from the high-pressure vessel 11 (state shown in FIG. 3C). . Next, the mask layer 3 on the polymer substrate 1 was removed with a special stripping solution (state shown in FIG. 3D).

  Through the above-described process, the polymer substrate 1 was obtained in which the dye 2 penetrated into the polymer substrate with the character patterns “A” and “B” as shown in FIG. That is, a polymer substrate 1 partially surface-modified with the dye 2 could be obtained. Since the dye 2 penetrates into the polymer substrate 1 at a high concentration, the dye 2 is difficult to peel off.

  As described above, in the polymer substrate surface modification method of this example, a mask layer in which the region to be surface modified on the substrate is an opening is formed on the substrate by a printing method such as a screen printing method in advance. Then, the organic material is infiltrated with the supercritical fluid through the opening, and the predetermined region on the substrate is selectively surface-modified. Therefore, in the surface modification method of this example, a predetermined region can be selectively surface-modified on the surface of the substrate without using a mold having a fine uneven pattern. There is no need to manufacture individual molds according to the pattern, the cost is low, and the process can be simplified.

  Further, in the surface modification method of the polymer base material of this example, the mask layer is closely attached to the polymer base material. Therefore, even if supercritical carbon dioxide in which an organic substance is dissolved is contacted from the mask layer side of the base material. Since the supercritical carbon dioxide in which the organic substance is dissolved does not enter between the mask layer and the polymer substrate, the pattern of the region to be surface-modified can be formed with higher accuracy.

[Evaluation of adhesion]
The adhesion of the dye 2 formed on the surface of the polymer substrate 1 obtained by the above process was evaluated. Specifically, the evaluation was performed by immersing the polymer substrate 1 in isopropyl alcohol which is a good solvent for the dye 2. For comparison, a polymer substrate (hereinafter referred to as a polymer substrate of Comparative Example 1) in which the dye is screen-printed on the polymer substrate 1 (the treatment for allowing the dye to penetrate into the polymer substrate using a supercritical fluid was not performed). ) And the adhesion was similarly evaluated. As a result, when the polymer substrate of Comparative Example 1 was immersed in isopropyl alcohol, the dye eluted and the printing disappeared. However, in the polymer substrate 1 produced in this example, the disappearance of the color of the character pattern portion was not observed. This is because, in the polymer substrate of Comparative Example 1, the dye does not penetrate into the substrate and is easily eluted, whereas in the polymer substrate of Example 1, the dye penetrates at a high concentration inside the polymer substrate. This is considered to be because the dye is in a state in which it is difficult to elute.

  In Example 2, an example in which the surface modification method of the present invention is applied to a plate used for biochemical analysis called micro-TAS (μ-TAS) will be described. A schematic configuration of the micro TAS produced in this example is shown in FIG.

  In the micro TAS 40 of this example, the pattern 42 of the organic material 43 as shown in FIG. 4A was formed on the polymer substrate 41. As the polymer substrate 41, a flat substrate made of polymethyl methacrylate resin (manufactured by Asahi Kasei Kogyo Co., Ltd., trade name: Delpet 560F) having a glass transition temperature Tg of about 100 ° C. was used. As the organic substance 43 forming the pattern 42, polyethylene glycol (PEG) having an average molecular weight of about 1000 was used. That is, in this example, a surface modification treatment is performed in which PEG 43 is infiltrated by bringing a supercritical fluid in which PEG 43 is dissolved into contact with a predetermined region on the surface of the polymer substrate 1 to make the predetermined region hydrophilic. Since the pattern part 42 on the surface of the polymer substrate to which the PEG 43 is added is hydrophilized, it is possible to cause a specimen, a reagent, or the like having a solute such as water to flow along the pattern part 42.

  As shown in FIG. 4A, the pattern 42 of the PEG 43 includes a circular portion 42a into which a liquid sample is injected, and a flow path 42b extending from the circular portion 42a along the longitudinal direction of the polymer substrate 41. The three branch channels 42c branched from the middle of the channel 42b, and three small circular portions 42d into which reagents formed at the respective tips of the three branch channels 42c were injected. In this example, the diameter of the circular portion 42a is 5 mm, the diameter of the small circular portion 42d is 2 mm, and the width of the flow path 42b and the branch flow path 42c is 300 μm. In this example, the surface of the polymer substrate 41 is a flat surface. The PEG 43 pattern 42 was formed on the polymer substrate 41 as described in Example 1 as follows.

  First, a mask layer was formed on the polymer substrate 41 as follows. A mask material was attached to an area other than the pattern part 42 of the PEG 43 to be formed on the polymer substrate by an ink jet printing method. In this example, a photosensitive resin (SU-8 manufactured by Kayaku Microchem Co., Ltd.) was used as the mask material as in Example 1, and the coating thickness of the photosensitive resin was 100 nm. Next, the polymer substrate 41 to which the photosensitive resin was adhered was dried at 70 ° C. for 1 hour, and further cooled at room temperature for 1 hour. Next, the mask material was cured by irradiating the mask material with ultraviolet rays to form a mask layer. In this way, a mask layer having the pattern part 42 of PEG 43 as an opening was formed on the polymer substrate 41.

  Next, the polymer substrate 41 on which the mask layer having the pattern portion 42 of the PEG 43 as an opening was formed was placed in the concave portion 31 of the high-pressure vessel 11 used in Example 1, and the inside of the high-pressure vessel 11 was sealed. Next, in the same manner as in Example 1, supercritical carbon dioxide in which PEG 43 is dissolved is brought into contact with the surface of the polymer substrate 41, and PEG 43 penetrates into the inside from the surface of the polymer substrate 41 exposed at the opening of the mask layer. I let you. At this time, PEG 43 softened by heating to 60 ° C. in supercritical carbon dioxide having a pressure P1 of 15 MPa and a temperature of 50 ° C. is dissolved in the substance dissolution tank 18, and the supercritical carbon dioxide in which the PEG 43 is dissolved is high pressure. It was introduced into the container 11 and retained. Subsequently, after the pressure P of supercritical carbon dioxide in which PEG 43 was dissolved was stabilized, the state was maintained for 30 minutes. Thereby, PEG 43 was infiltrated with the supercritical carbon dioxide from the surface of the polymer substrate 41 exposed at the opening of the mask layer to the inside thereof. However, at this time, supercritical carbon dioxide also contacts a region other than the opening of the mask layer. Since photosensitive resin is formed in this region, PEG 43 penetrates into the polymer substrate 41 in this region. (The surface of the polymer substrate 41 in this region is not modified).

  Next, the inside of the high-pressure vessel 11 was opened to the atmosphere in the same manner as in Example 1, and the polymer substrate 41 was taken out from the high-pressure vessel 11. Thereafter, the mask layer was removed with a special stripping solution. In this manner, micro TAS 40 made of polymethyl methacrylate resin in which PEG 43 permeated only into the pattern 42 portion on the surface of the polymer substrate 41, that is, only the portion to which PEG 43 was added, was obtained. In the micro TAS 40 manufactured in this example, only the surface portion (the pattern 42 portion) of the polymer substrate 41 into which PEG 43 has permeated is hydrophilized.

  Next, the wettability on the surface of the micro TAS 40 of this example produced as described above was evaluated. For comparison, a micro TAS (hereinafter referred to as micro TAS of Comparative Example 2) in which a PEG pattern was simply ink-jet printed on a polymer substrate (the treatment for infiltrating PEG into the polymer substrate using a supercritical fluid was not performed). ) And wettability was similarly evaluated. As a result, in the micro TAS of Comparative Example 2, the water contact angle of the surface portion to which PEG was added was about 55 °, whereas the micro TAS 40 (micro TAS subjected to surface modification treatment) was used. ), The contact angle of water on the surface to which PEG was added was about 10 °. In other words, like the micro TAS 40 produced in this example, the wettability of the part to which PEG is added is greatly improved by performing the surface modification treatment in contact with supercritical carbon dioxide (hydrophilicity is improved). ) In addition, when a water droplet is dropped near the circular portion 42a formed on the micro TAS 40 manufactured in this example, the water is transmitted along the flow passage 42b and the branch flow passage 42c and reaches the small circular portion 42d. It could be confirmed.

  Moreover, when the microTAS40 of this example was immersed in water for 24 hours and then the wettability was confirmed again, the contact angle of water hardly changed. Furthermore, after the micro TAS 40 of this example was left in the atmosphere for 10 months, the wettability of the region to which PEG was added was confirmed. The contact angle of water was 13 °, and good wettability was maintained. I understood that. This is considered to be because wettability is stably maintained because PEG penetrates into the polymer substrate at a high concentration.

  In Example 3, as in Example 2, an example in which the surface modification method of the present invention is applied to a micro TAS will be described. However, in this example, in order to form a finer organic material pattern on the polymer substrate than in Example 2, an example will be described in which a recess (groove) is provided in a region to be surface-modified on the polymer substrate.

  A schematic configuration diagram of the micro TAS produced in this example is shown in FIG. In the micro TAS 50 of this example, as shown in FIGS. 5A and 5B, the surface of the polymer substrate 51 is similar to the pattern of PEG formed on the surface of the polymer substrate of the micro TAS manufactured in Example 2. A groove pattern 52 was formed, and PEG 53 was infiltrated into the groove pattern. In the micro TAS 50 of this example, the dimensions of the groove pattern 52 are as follows. The diameter of the circular part 52a is 5 mm, the widths of the flow path 52b and the branch flow path 52c are both 100 μm, the diameter of the small circular diameter part 52d is 2 mm, and the depths of the circular part 52a, the small circular diameter part 52d and the groove pattern 52 are In either case, the thickness was 100 μm. In this example, PMMA (polymethylmethacrylate) resin is used as the polymer substrate 51, and PEG (polyethylene glycol) 53 is used as an organic substance that penetrates into the groove pattern 52. Next, a manufacturing method of the micro TAS 50 of this example will be described with reference to FIGS.

  First, a mold having an uneven pattern opposite to the groove pattern 52 formed on the polymer substrate 51 is prepared, and a groove pattern 52 as shown in FIG. 5 is formed on the surface by injection molding using the mold. A polymer substrate 51 was prepared (state shown in FIG. 6A). In this example, the concavo-convex pattern on the mold is formed by precision machining, but the concavo-convex pattern may be formed on the mold by applying a lithography method.

  Next, as shown in FIG. 6B, a mask layer 54 is formed in a region other than the groove pattern 52 (region to be surface modified) of the polymer substrate 51 formed by the above-described method in the same manner as in the second embodiment. Formed. That is, a mask layer 54 having the groove pattern 52 as an opening was formed on the polymer substrate 51 using an ink jet printing method. In this example, as the mask layer 54, a photosensitive resin (SU-8, manufactured by Kayaku Microchem Co., Ltd.) was used as in Example 2, and the coating thickness of the photosensitive resin was 100 nm.

  Next, the polymer substrate 51 on which the mask layer 54 was formed was placed in the recess 31 of the high-pressure vessel 11 used in Example 1, and the inside of the high-pressure vessel 11 was sealed. Next, in the same manner as in Example 2, the surface of the polymer substrate 51 is brought into contact with the supercritical carbon dioxide 55 in which PEG 53 is dissolved, and the PEG 53 is exposed from the surface of the polymer substrate 51 exposed at the opening of the mask layer to the inside thereof. Infiltrated (step of FIG. 6C).

  Next, the inside of the high-pressure vessel 11 was opened to the atmosphere in the same manner as in Example 1, and the polymer substrate 51 was taken out from the high-pressure vessel 11 (state shown in FIG. 6D). Next, the mask layer 54 was removed with a special stripping solution (state shown in FIG. 6E). Thus, a micro TAS 50 made of polymethyl methacrylate resin in which PEG 53 permeated only into the groove pattern 52 portion on the surface of the polymer substrate 51 (surface-modified) could be obtained. In the micro TAS 50 manufactured in this example, only the groove pattern 52 portion of the polymer substrate 51 into which PEG 53 has permeated is hydrophilized.

  As in the surface modification method of this example, by forming a recess in the region to be surface-modified in advance on the polymer substrate, an organic substance pattern can be easily and accurately formed even with a finer pattern. I found out that I could do it. In fact, in this example, PEG could be infiltrated with a flow path pattern having a width of about 1/3 of the flow path pattern width of the micro TAS produced in Example 2.

  Further, the wettability of the micro TAS 50 produced in this example was also evaluated in the same manner as in Example 2. As a result, the same result as in Example 2 was obtained. In other words, it was confirmed that the wettability was improved only in the pattern portion infiltrated with PEG, and it was made hydrophilic and the wettability was stably maintained for a long time.

  In this example, the region to be surface-modified on the polymer substrate is formed with a concave portion, but the present invention is not limited to this and may be formed with a convex portion.

  In this example, when the groove pattern is formed in a predetermined pattern on the polymer base material, the groove pattern is formed using a mold, but the present invention is not limited to this. For example, a groove pattern corresponding to the organic material pattern may be formed on the polymer substrate by the following method. First, a mask layer is formed on a flat polymer substrate so that the region to be surface-modified is an opening. Next, grooves (concave portions) may be formed in the openings of the mask layer (regions where the surface of the polymer substrate is exposed) by a method such as reactive ion etching.

  In Example 4, an example in which the surface modification method of the present invention is applied to a polymer substrate having a three-dimensional surface will be described. Specifically, in this example, when circuit wiring is performed on a module substrate of a one-chip type lens module that integrally includes a lens and an image sensor that detects image formation by the lens as an electrical signal, An example in which the surface modification method is applied will be described.

  A schematic configuration of the lens module manufactured in this example is shown in FIG. As shown in FIGS. 7A and 7B, the lens module 60 manufactured in this example includes a base 61 (polymer substrate), a lens 62, and an image sensor 63. One surface 61a (upper surface in FIG. 7A) of the substrate 61 is a substantially flat surface, and the other surface 61b (lower surface in FIG. 7A) is a concave solid surface. As shown in FIG. 7A, the lens 62 is mounted integrally with the base material 61 on the central portion of the flat surface 61a of the base material 61, and the image sensor 63 has a bottom 61e of the concave solid surface 61b. Installed on top. And in the lens module 60 of this example, as shown in FIG.7 (b), the some solid wiring 64 which connects the upper part 61d and the bottom part 61e of the concave solid surface 61b of the base material 61 is formed. The three-dimensional wiring 64 is a wiring necessary for mounting the image sensor on the concave three-dimensional surface 61 b of the base material 61.

  As the substrate 61, a polymer substrate made of amorphous polyolefin having a glass transition temperature Tg of about 145 ° C. was used. The three-dimensional wiring 64 was formed of a Cu film. The manufacturing method of the three-dimensional wiring 64 is as follows.

  First, a plating base pattern is formed in a region corresponding to the wiring pattern on the concave three-dimensional surface 61b of the substrate 61. Specifically, a plating base pattern was formed on the three-dimensional surface 61b of the substrate 61 as follows.

  First, a mask layer was formed in a region not corresponding to the wiring pattern portion 64 on the three-dimensional surface 61b of the substrate 61 in the same manner as in Example 2. That is, a mask layer having the wiring pattern portion 64 as an opening was formed on the substrate 61 using an inkjet printing method. In this example, as the mask layer, a photosensitive resin (manufactured by Kayaku Microchem Co., Ltd., SU-8) was used as in Example 2, and the coating thickness of the photosensitive resin was 100 nm.

  Next, the base material 61 on which the mask layer was formed was placed in the recess 31 of the high-pressure vessel 11 used in Example 1, and the inside of the high-pressure vessel 11 was sealed. Next, in the same manner as in Example 2, the surface of the substrate 61 is brought into contact with supercritical carbon dioxide in which a metal complex (substance) is dissolved so that the metal complex is exposed at the opening of the mask layer. 61 It was stabilized by permeating the inside from the surface.

  In this example, a bis (acetylacetonato) palladium metal complex was used as the metal complex, and a hexane solution of the metal complex was dissolved in supercritical carbon dioxide. Metal complexes that can be dissolved in supercritical carbon dioxide and reduced to become plating nuclei include platinum dimethyl (cyclooctadiene), bis (cyclopentadienyl) nickel, bis (acetylacetonate) palladium, hexachloroacetylacetate. Natopalladium or the like can also be used.

  Thereafter, the substrate 61 was immersed in a reducing agent (sodium borohydride) to reduce the metal complex to form metal fine particles. In this way, a plating base was formed in a region corresponding to the wiring pattern on the concave three-dimensional surface 61b of the substrate 61.

  Next, Cu was plated on the concave solid surface 61b side of the substrate 61 by electroless plating. At this time, the Cu film grows only in a portion (plating base portion) where the metal complex has permeated and the surface is modified. In this example, a 10 μm thick Cu film was formed. Finally, the mask layer was removed with a special stripping solution. Thus, the three-dimensional wiring 64 made of the Cu film was formed on the three-dimensional surface 61b of the base member 61 as shown in FIG. As described above, even when the polymer substrate to which the surface modification method of the present invention is applied has a three-dimensional structure as in this example, a mask layer having a wiring pattern portion as an opening is formed by an ink jet method. By bringing a supercritical fluid in which a metal complex (substance) is dissolved into contact with each other, the metal complex can be infiltrated only into the wiring pattern portion to modify the surface. Therefore, by using the surface modification method of the present invention, wiring to a three-dimensional part, which has been impossible in the past, can be made possible.

  Next, the adhesion of the three-dimensional wiring 64 of the lens module 60 produced in this example was evaluated. Specifically, a peeling test using an adhesive tape was performed on the three-dimensional wiring 64 formed on the three-dimensional surface 61 b of the base material 61. For comparison, a lens module that does not subject the solid surface 61b of the substrate 61 to surface modification treatment (treatment of allowing a metal complex to permeate the substrate using supercritical carbon dioxide) (hereinafter referred to as the lens module of Comparative Example 3). The adhesiveness was examined. The results are shown in FIG. As is clear from FIG. 8, in the lens module of Comparative Example 3, the three-dimensional wiring was easily peeled off in the peeling test. On the other hand, in the lens module 60 of this example, it was found that the three-dimensional wiring 64 was difficult to peel off, and the adhesion was greatly improved. Furthermore, when the adhesion of the three-dimensional wiring 64 was confirmed after leaving the lens module after the surface modification treatment in the atmosphere for 10 months, it was found that it was difficult to peel off and good adhesion was maintained.

  In Example 5, a micro TAS (FIG. 4) having the same structure as that of Example 2 was produced by a surface modification method different from that of Example 2. The base material of the micro TAS produced in this example, the organic material, and the pattern formed on the base material were the same as those in Example 2. A method for manufacturing the micro TAS of this example will be described with reference to FIGS.

  First, as shown in FIG. 9A, a mask layer 44 having a pattern part 42 of PEG 43 as an opening was formed on a polymer substrate 41 in the same manner as in Example 2. Next, a layer 45 of PEG 43 that penetrates the polymer substrate 41 was formed on the mask layer 44. Specifically, PEG 43 (average molecular weight 1000) heated to 60 ° C. was applied onto the mask layer 44 and the opening 42 of the mask layer 44 as shown in FIG. 9B. In this example, as shown in FIG. 9B, the example in which the PEG layer 45 is applied over the entire surface of the mask layer 44 has been described, but the present invention is not limited to this. In the surface modification method of this example, it is necessary to apply PEG 43 to the opening 42 of the mask layer 44, but it is not necessary to apply PEG 43 to other areas on the mask layer 44.

  Next, the polymer substrate 41 on which the PEG 43 layer 45 was formed was placed in the recess 31 of the high-pressure vessel 11 used in Example 1, and the inside of the high-pressure vessel 11 was sealed. Next, supercritical carbon dioxide having a pressure P1 = 15 MPa and a temperature of 50 ° C. was introduced into the high-pressure vessel 11 and retained (state shown in FIG. 9B). And after the pressure of supercritical carbon dioxide was stabilized, the state was maintained for 30 minutes. At this time, by bringing the surface of the polymer substrate 41 into contact with supercritical carbon dioxide, a part of the PEG layer 45 formed in the opening 42 of the mask layer 44 is opened together with the supercritical carbon dioxide. It penetrates into the inside from the surface of the polymer substrate 41 exposed to the part (state of FIG. 9C). That is, in this example, the supercritical carbon dioxide in which PEG is dissolved is not brought into contact with the polymer substrate to infiltrate the inside of the polymer substrate as in Example 2, but PEG is applied on the polymer substrate in advance. Then, PEG is infiltrated into the polymer substrate by bringing supercritical carbon dioxide into contact therewith.

  In this example, the high-pressure apparatus 100 shown in FIG. 2 is used. However, since the supercritical carbon dioxide introduced into the high-pressure vessel 11 does not need to be dissolved as described above, the high-pressure apparatus of this example is used. No PEG was charged into the substance dissolution tank 18 in 100.

  In addition, when supercritical carbon dioxide is brought into contact with the polymer substrate, supercritical carbon dioxide also comes into contact with a region other than the opening of the mask layer, but since the mask layer is formed in this region, in this region, PEG does not penetrate into the polymer substrate 41 (the surface of the polymer substrate 41 in this region is not modified).

  Next, after infiltrating PEG 43 into a predetermined region of the polymer substrate 41, the inside of the high-pressure vessel 11 was opened to the atmosphere in the same manner as in Example 1, and the polymer substrate 41 was taken out from the high-pressure vessel 11 (see FIG. 9C). Status). Next, PEG 43 that did not penetrate into the polymer substrate 41 was removed by washing with water or an alcohol such as ethyl alcohol (state of FIG. 9D). Next, the mask layer 44 was removed with a special stripping solution (state shown in FIG. 9E). In this manner, micro TAS 40 made of polymethyl methacrylate resin in which PEG 43 permeated only into the pattern 42 portion on the surface of the polymer substrate 41, that is, only the portion to which PEG 43 was added, was obtained. In the micro TAS 40 produced in this example, only the surface portion (the pattern 42 portion) of the polymer substrate 41 infiltrated with PEG 43 is hydrophilized as in the second embodiment.

  Further, the wettability of the micro TAS 40 produced in this example was evaluated in the same manner as in Example 2. As a result, the same result as in Example 2 was obtained. In other words, it was confirmed that the wettability was improved only in the pattern portion infiltrated with PEG, it was made hydrophilic, and the wettability was stably maintained for a long time.

  In the above Examples 1 to 5, when the supercritical fluid was brought into contact with the polymer substrate, the bolting was performed in order to maintain the hermetic state in the high-pressure vessel, but the present invention is not limited to this, and any means Can be used. For example, a rotary lid seal mechanism or the like can be used. Moreover, you may employ | adopt the method of sealing a mating surface with the force of a press using a press apparatus.

  According to the surface modification method for a polymer substrate of the present invention, a predetermined region (region of a predetermined pattern) on a polymer substrate can be selectively surface-modified. In particular, since the surface can be easily modified even in a very fine region, the method for modifying the surface of the polymer substrate of the present invention includes a micro TAS and biochip that require surface modification with a fine pattern, Or it is especially suitable for manufacture of a three-dimensional wiring device etc.

1 is a perspective view of the polymer substrate produced in Example 1. FIG. FIG. 3 is a schematic configuration diagram of the high-pressure apparatus used for surface modification of the polymer substrate in Example 1. 3A to 3D are diagrams showing a procedure of a method for forming a pattern of an organic substance on the polymer substrate of Example 1. FIG. 4 is a schematic configuration diagram of a micro TAS manufactured in Example 2, FIG. 4 (a) is a perspective view, and FIG. 4 (b) is an AA ′ sectional view in FIG. 4 (a). is there. FIG. 5 is a schematic configuration diagram of a micro TAS manufactured in Example 3, FIG. 5 (a) is a perspective view, and FIG. 5 (b) is a cross-sectional view along BB ′ in FIG. 5 (a). is there. FIGS. 6A to 6E are diagrams showing a procedure of a method for forming a pattern of an organic substance on the polymer substrate of Example 3. FIG. 7 is a schematic configuration diagram of a lens module manufactured in Example 4, FIG. 7A is a cross-sectional view along CC ′ in FIG. 7B, and FIG. 7B is a three-dimensional surface side. FIG. FIG. 8 is a diagram showing the results of a three-dimensional wiring peeling test of the lens module manufactured in Example 4. FIGS. 9A to 9E are diagrams showing a procedure of a method of forming an organic substance pattern on the polymer substrate of Example 5. FIG.

Explanation of symbols

1, 41, 51 Polymer substrate 2, 43, 53 Substance 3, 44, 54 Mask layer 5, 55 Supercritical fluid in which substance is dissolved

Claims (7)

A method for surface modification of a polymer substrate using a supercritical fluid,
Forming a mask layer having an opening with a predetermined pattern in contact with the polymer substrate;
Surface modification comprising bringing a supercritical fluid containing a substance into contact with the surface of the polymer base on the mask layer side and allowing the substance to permeate the polymer base through an opening in the mask layer Method. A method for surface modification of a polymer substrate using a supercritical fluid,
Forming a mask layer having an opening with a predetermined pattern in contact with the polymer substrate;
Forming a layer of material at least in the opening of the mask layer;
A surface modification method comprising: bringing a supercritical fluid into contact with the layer of the substance, and allowing the substance to permeate the polymer substrate through the opening of the mask layer. The surface modification according to claim 1, further comprising preparing a polymer base material on which at least one of a concave portion and a convex portion is formed on the surface of the polymer base material corresponding to the opening of the mask layer. Method. The surface modification method according to claim 1, wherein the mask layer is formed of a polymer material. The surface modification method according to claim 1, wherein the mask layer is formed by a printing method. The surface modification method according to any one of claims 1 to 5, wherein the substance is an organic substance. The polymer base material surface-modified using the surface modification method as described in any one of Claims 1-6.