JP4104964B2 - MASK FOR FORMING THIN FILM PATTERN OF LAMINATED STRUCTURE COMPRISING PATTERNED MASK COATING AND SUPPORT AND METHOD FOR PRODUCING THE SAME - Google Patents

Description

【００２２】
表１より明らかなように短寸法、累積ピッチ誤差、マスク開孔部内Ｒのいずれも実施例の方が微小であり、精密且つ精巧な寸法精度の良いマスクを形成することができることが明らかとなった。
【００２３】
【発明の効果】
以上に説明したように本発明の薄膜パターン形成用マスクは、フォトエッチング法によるメタルマスクのコストメリットとフォトリソグラフィ法によるリフトオフの形状及び寸法安定性を具備した新規なマスクであり、少ない工数で比較的容易に高精度の微細パターンを形成することができ、繰り返し使用することもでき経済的に安価で、従来の薄膜パターン形成用マスクと比べて種々の面で優れた効果を奏する。
【図面の簡単な説明】
【図１】本発明の薄膜パターン形成用マスクを用いた機能性薄膜の生成方法の工程図
【図２】本発明のマスク被膜に感光性高分子を用いたフォトリソ法による薄膜パターン形成用マスクの製造方法の工程図
【符号の説明】
１ 薄膜パターン形成用マスク
２´ マスク被膜（パターニング前）
２ マスク被膜（パターニング後）
３ 支持体
４ 薄膜パターン形成領域（マスク被膜開口）
５ 被成膜基板
６ 機能性薄膜
７ マスク
８´ レジスト膜（パターニング前）
８ レジスト膜（パターニング後）[0001]
BACKGROUND OF THE INVENTION
In the present invention, a thin film having characteristics such as metal, inorganic or organic conductivity (hereinafter referred to as a functional thin film) used in a manufacturing process of a semiconductor element or a display panel is accurately formed into an arbitrary fine shape with few steps. The present invention relates to a thin film pattern forming mask for processing and a manufacturing method thereof.
[0002]
[Prior art]
Since parts for semiconductor elements or display panel components are small in size and require processing accuracy, various balances of accuracy, man-hours, and cost are considered as important factors in their manufacture. I came.
As a method for obtaining a functional thin film, there is a technique for forming, depositing or growing a metal, ceramics, organic substance, inorganic substance or the like on a substrate, and a vapor deposition method, a sputtering method, a vapor phase growth method or the like is used as a general method. Has been. As a technique for processing a functional thin film into an arbitrary shape, a lift-off method, dry etching in a vacuum, or the like is often used, but all of them have a film thickness of about 1 to 4 μm in order to mask a non-deposition site, that is, protect it. A photolithographic technique for processing a photoresist of a certain degree into an arbitrary shape by a photochemical reaction has been fundamental. Photolithographic technology is a method of applying a photoresist on a substrate, exposing a desired pattern using a photomask, developing the resist with a specific chemical, obtaining a resist pattern, and then etching, A fine pattern is formed on the substrate by performing a series of steps such as resist peeling. Since the photolithography method can produce a fine pattern with good reproducibility, the dimensional accuracy of a functional thin film produced using this technique is excellent. However, since the manufacturing process is complicated and time-consuming, the manufactured product has been expensive.
On the other hand, as a method of forming a fine pattern at low cost by simplifying the process and reducing the number of processes, there is a method using a metal mask having an opening in a film formation region. In this method, a non-deposition site on the substrate is masked with a metal mask in advance, and a thin film is selectively formed only at a desired site by sputtering or vapor deposition.
However, these two types of mask processes do not satisfy both accuracy and man-hours. Although the photolithography technique is excellent in precision such as thin film dimensional reproducibility and fine workability, there is a problem in terms of man-hours because it is necessary to form a resist mask pattern on the target substrate each time a functional thin film is formed. On the other hand, in the metal mask technology, when the metal mask manufacturing method is photoetching, the processing accuracy itself is much inferior to the resist accuracy, and the alignment accuracy between the metal mask and the deposition substrate has physical limitations, etc. Both the dimensional accuracy and the photolithography method were not reached. However, when a metal mask is made, it can be used repeatedly until it breaks, and there is an advantage that productivity is remarkably high.
In addition to the photoetching method, there is an electroforming method for producing the metal mask. The electroforming method is a method in which after a metal is electrodeposited on a mother die, the electrodeposited metal is removed from the mother die to obtain a pattern having irregularities opposite to the mother die. As an advantage, it was faithfully transferred from the master mold, making it ideal for molds that require complex designs and mirror surfaces. However, the separated electroformed mask has low mechanical strength and requires special care in handling.
The metal mask formed by the electroforming method has a relatively higher accuracy than that formed by the photoetching method, and depends on the accuracy of the mother die. However, the matrix is generally formed of a thick film photoresist, and if the replica is an electroformed mask, the dimensional accuracy is naturally inferior to that formed by photolithography. In addition, the cost is high and it is often used for special purposes.
In view of such a situation, a thin film pattern forming method that can form a high-precision fine pattern, has a simple manufacturing process, and is economically inexpensive has been desired.
Therefore, the inventors of the present invention have invented a novel mask for forming a thin film pattern having the cost merit of a metal mask by a conventional photoetching method and the shape and dimensional stability of lift-off by a photolithography method.
[0003]
[Problems to be solved by the invention]
The present invention provides a mask for forming a thin film pattern having a new laminated structure, which eliminates the decrease in accuracy when using a conventional metal mask and eliminates the increase in cost when using a photolithography, and a method for manufacturing the same. It is.
[0004]
[Means for Solving the Problems]
The present invention relates to a mask and a mask manufacturing method for forming a pattern of a metal, inorganic or organic functional thin film used in the manufacturing process of a semiconductor element or a display panel. The present invention relates to a mask for forming a thin film pattern for processing into an arbitrary fine shape with few steps and a method for manufacturing the same.
The present invention
“1. For thin film pattern formation, the mask film side of the mask for forming a thin film pattern is attached to the deposition target substrate, and a functional thin film having a shape conforming to the opening pattern of the mask film is formed by sputtering or vapor deposition from the mask support side. In the mask manufacturing method A polymer film formed on one side of the metal plate of the mask support, exposed to the mask coating pattern on the photosensitive polymer film, and subjected to a development process and a curing process to be cured on one side of the metal sheet A mask coating pattern of the film is formed, and then a resist pattern for etching the metal plate corresponding to the mask coating pattern is disposed on the opposite side of the metal plate of the mask support, and the mask plate and the resist coating are used as etching resists to form the metal plate. A method for producing a mask for forming a thin film pattern having a laminated structure, wherein etching is performed from both sides to form a through-opening corresponding to a film pattern on a metal plate, and then the resist pattern for etching is removed.
2. A mask for forming a thin film pattern having a laminated structure, wherein the photosensitive polymer film formed on one side of the mask support metal plate according to claim 1 is a semi-cured photosensitive polyimide film semi-cured with a polyimide resin precursor. Production method.
3. 2. The production of a mask for forming a thin film pattern having a laminated structure according to claim 1, wherein the photosensitive polymer film formed on one side of the mask support metal plate is a mask film made of an acrylic, epoxy or rubber resin. Method.
4). The laminated structure according to any one of claims 1 to 3, wherein an opening size of a mask film of each opening forming a pattern of a thin film pattern forming mask is smaller than an opening size of an opposing mask support. A method for manufacturing a mask for forming a thin film pattern.
5. 5. The manufacturing method of a thin film pattern forming mask having a laminated structure according to claim 4, wherein the opening of the mask support for forming the pattern of the thin film pattern forming mask is gradually narrowed toward the mask film. Method.
6). A thin film pattern forming mask having a laminated structure manufactured by the manufacturing method according to claim 1. "
About.
[0005]
DETAILED DESCRIPTION OF THE INVENTION
The thin film pattern forming mask of the present invention is a mask having a structure in which a patterned mask film and a support having a shape corresponding to the mask film pattern are laminated. The mask film side of the mask for forming a thin film pattern is brought into contact with the film formation substrate, and the functional thin film having a shape corresponding to the opening pattern of the mask film is formed by performing sputtering or vapor deposition from the support side of the mask. The support, which is one of the constituent features of the present invention, functions as a reinforcing material for the mask coating, and supports and reinforces the strength, posture, and pattern shape of the mask coating. By providing a support, the mask can be used repeatedly. The mask support is used only for mask reinforcement and ease of handling, and is not directly involved in the pattern formation of the functional thin film. The pattern of the functional thin film is formed faithfully to the shape of the opening pattern of the mask coating, and the dimensional accuracy of the functional thin film is due to the dimensional accuracy of the mask coating.
[0006]
There are several methods for creating a mask for forming a thin film pattern. For example, using a metal substrate as a support, laminating a patterned mask coating on one side of the metal substrate, forming a resist pattern for etching a metal plate corresponding to the mask coating pattern on the back side of the metal substrate, A method in which the mask film on the front surface functions as an etching resist, the metal support is patterned by etching from both sides of the metal substrate, and finally only the resist film on the back surface is removed with a solvent is suitable. This method pays attention to the difference between the solvent of the mask film and the etching resist of the metal substrate, and uses a mask film and etching resist insoluble in the etching solution of the metal plate, the developing solution of the mask film and the etching resist film, and the stripping solution. Thus, this is an excellent method utilizing the patterning process selectivity, and an accurate mask can be formed with a small number of steps.
[0007]
An example of the manufacturing method in the functional thin film pattern forming mask of the present invention will be shown below. The following four methods describe only the mask film pattern formation method, and the support patterning method will be described later.
(Mask coating pattern formation method)
(1) Photolithographic method
A method in which a photosensitive resin is applied and dried on the surface of a support to form a resin film on one surface, and a mask film having a desired pattern is formed by photolithography. Since the photolithography method has excellent microfabrication accuracy, a mask with good dimensional accuracy can be formed. The processing method is as follows. First, a photosensitive resin is applied to a support and dried to form a photosensitive polymer film, and the photosensitive polymer film is exposed to a mask pattern, followed by development, rinsing, drying, curing, and the like. The pattern of the photosensitive polymer film is formed on the support through the above.
(2) Pasting method
A method of pasting a mask film on which a pattern has been formed in advance on a support. In the attaching method, a mask film having a desired shape is formed in advance by a photolithography method or other methods, and the mask film on which the pattern has been formed is attached to a support. If the mask film pattern forming method is not a photolithography method, a non-photosensitive resin may be used. Examples of the pattern forming method include dry etching, wet etching, a machining method, and molding by an electroforming method. The pattern formation method by electroforming is relatively excellent in accuracy, and a resin material or the like that is a mask coating material is poured into an electroformed structure that is a mask coating matrix and is defoamed and solidified to be faithful to the matrix. In this method, a mask film having a pattern shape is formed, and the mask film is removed from the matrix and attached to a support. For the purpose of improving releasability from the mother mold, a fluororesin film or the like may be formed in advance on the surface of the mother mold, and an organic material such as epoxy resin, polyimide resin, acrylic resin, or rubber resin is used as a mask film material Of course, inorganic materials such as fluororesin, ceramics such as alumina powder, and the like may be used. The patterned mask film is laminated on a metal substrate to be a support. If the mask material is thermoplastic, it may be heat-bonded, and otherwise, an adhesive may be used.
(3) Printing method
A method of printing a mask film having a desired pattern on a support by screen printing or the like. The screen printing method is a method in which the screen of the non-mask coating part is closed, the resin that becomes the mask coating is selectively extruded from the mesh, and printed only on the desired part on the support, and the screen is supported. A special frame is used on the body while securing a specified gap, and a mask coating resin such as epoxy ink is extruded onto the support with a squeegee, etc., and the screen pattern is transferred to form a mask coating pattern. To do. Since the screen is displaced by pressing the squeegee or causes ink bleeding, it is necessary to determine the application in consideration of accuracy.
(4) Mold method
A method of forming a mask-coating-shaped mold to be obtained on the surface of a support on the support, filling the mold with a mask-coating raw material, solidifying the mold, and forming a mask-coating pattern using the mold on the support. First, make a pattern of the desired shape on the support. As a method for forming a mold, the support may be dug to form a groove, or the mold may be constructed on the support. There are methods for forming grooves on the support using half etching, sand blasting, machining, etc., and when a mold is constructed on the support, electroforming or the like is used on the support. A mold may be formed or other methods may be used. The mold is filled with a mask coating material and solidified to form a mask coating having a desired shape.
Using such a method, a mask film having a desired shape can be formed on the support.
[0008]
(Support pattern formation method)
Next, a method for forming a support pattern will be described. There are several methods for forming a support pattern. For example, the opening corresponding to the shape of the thin film pattern may be mechanically machined, or may be formed by etching or other methods. As a method by etching, there is a method in which a metal plate is used as a support, an etching resist having a desired pattern is formed on both sides or one side, and a pattern is formed by etching. In addition, there is a method of forming a pattern of the support by using a material insoluble in an etching solution or the like for the mask film, and functioning the patterned mask film on the support as an etching resist. Of course, both the etching resist and the patterned mask film may be used as the support resist, and even when the mask film pattern is formed, a resist film pattern of the same material as the mask film is formed on the back surface by double-sided exposure. Good.
[0009]
(Method for forming a thin film pattern having a laminated structure)
As for the processing order of the mask coating and the support, the patterned mask coating may be applied to a previously patterned support, and the pattern formation of the support is performed after the patterned mask coating is laminated on the support. May be performed. It is preferable to form a pattern on the support after laminating a patterned mask film on the support in terms of pattern suitability, accuracy, and ease of processing.
It is preferable to form the mask for forming a thin film pattern of the present invention by combining the pattern forming method for the mask film and the pattern forming method for the support shown above, but the thin film pattern forming mask having a laminated structure using other methods. May be formed.
The resist film for forming the pattern of the support and the mask film may be formed of the same material, and in this case, it is not necessary to remove the resist. If you try to remove it forcibly, the mask film may be peeled off. If it does not interfere with the formation of a functional thin film, such as being removed by a solvent, acid, alkali, etc. There is no need to peel off.
[0010]
Next, a photosensitive polymer is used for the mask coating, a mask coating pattern is formed by photolithography on one side of the metal plate of the mask support, and then a resist pattern for etching the metal plate is formed on the opposite side of the mask support. The method of the present invention in which the mask coating and the resist coating function as a resist and patterning the support by etching will be further described.
One of the major features of the mask manufacturing method by the photolithography method is that a photosensitive resin is used for the mask film, and a mask with fine processing accuracy can be formed by using the photolithography technique.
A preferable method for manufacturing a mask for forming a thin film pattern by photolithography is (1) pattern formation of a photosensitive polymer film, (2) pattern formation of a resist for etching a metal substrate, (3) etching of a metal substrate, and (4) unnecessary. It consists of a resist peeling process.
[0011]
In the pattern formation of the first photosensitive polymer film, a pattern is formed on the film formed on the surface of the support by photolithography. Here, as in general photolithography, the process starts with degreasing the metal substrate to be the support. Then, a photosensitive resin is applied to one surface of the metal substrate after degreasing and dried to form a photosensitive polymer film. Here, a photosensitive resin having resistance to a strong acid, a weak alkali, an organic solvent and the like after film formation was used. Next, the mask pattern is exposed using a photomask prepared in advance on the photosensitive polymer film uniformly formed on the substrate. As a result, the exposed photosensitive polymer film becomes insoluble in the developer by the photochemical reaction. This is the same property as a negative type resist. A desired photosensitive polymer film pattern can be formed on the metal substrate by performing development, rinsing, drying, and curing. What is necessary is just to select suitably the temperature of the solvent used by image development and a rinse process, the temperature of cure, and various conditions corresponding to the photosensitive resin.
[0012]
Second, an etching resist pattern is formed on the back side of the metal substrate. Before applying the resist, the metal substrate is again pretreated such as degreasing. Then, a solvent-soluble photoresist is applied to the back side of the metal substrate, pre-baked to form a resist film on the back side of the metal substrate, and a metal substrate etching pattern is exposed there. The etching pattern for the metal substrate has a shape corresponding to the opening of the photosensitive polymer film on the surface side. In the present specification, the meaning that “the support opening corresponds to the mask coating opening” means that the support opening forms an opening including the mask coating opening and has a through-hole in the shape of the mask coating opening. Show. Therefore, for example, a support opening smaller than the mask coating opening cannot be said to have a corresponding shape, and a round support opening including the square mask coating opening can be said to have a corresponding shape.
The patterning of the etching resist can be easily matched with the pattern on the front surface by using alignment exposure with the back surface. When the mask of the present invention is used, the functional thin film pattern forming mask of the present invention is used in order to deposit the functional thin film from the support side by placing the photosensitive polymer film side of the mask in intimate contact with a substrate such as glass. In this pattern, it is necessary that the support opening and the mask coating opening have a penetrating portion. Furthermore, the shape accuracy can be improved when the opening size of the support is somewhat larger than the mask opening size of the photosensitive polymer film. For example, one mask film opening formed with one larger opening on the support, or two mask film openings formed with an opening on one support containing them There is. Of course, a plurality of mask openings may be included in one support opening. However, in the latter example, there is a risk that the coating film strength of the mask may be lowered. Therefore, the resist pattern may be formed in consideration of strength and processing accuracy.
After exposing the resist pattern to the etching film applied on the back side of the metal substrate, an etching resist pattern is formed on the back side through processes such as development, rinsing, drying, and post-baking.
[0013]
Third, an etching process is performed on the metal substrate on which the photosensitive polymer film and the etching resist pattern formed on the front and back surfaces are formed. On the surface side, since the patterned photosensitive polymer film functions as an etching resist, the portion of the metal substrate where the photosensitive polymer film is present is not corroded, but the portion where it is not present is corroded. On the back side, the metal substrate where the resist film exists is not corroded, but the part where the resist film does not exist is corroded. In this manner, the metal plate is etched from both sides, and the photosensitive polymer film opening and the support opening are penetrated. This method can be used by using a mask film that is resistant to an etching solution, a resist film developer and a stripping solution in advance.
As for the support shape, the mortar shape is such that the opening cross section of the metal substrate is not vertical but gradually decreases toward the opening of the mask coating. Make . By adopting such a shape, a thin film pattern that is more faithful to the mask shape can be formed. Also, if the metal substrate opening dimension is sufficiently larger than the photosensitive polymer film side opening dimension, the tolerance for the position alignment of the opening pattern center between the already formed photosensitive polymer film pattern and the etching resist pattern on the back surface can be increased. There is also an advantage that alignment control is simplified.
[0014]
Fourth, an unnecessary resist film is removed. The etching resist on the back surface used in the manufacturing process of the functional thin film pattern forming mask is not necessary in the final shape, and is removed. This step is not necessary for those that do not require removal of the resist film on the back side, but resist is usually not required as a mask, and the resist may fall off during functional thin film formation, which may hinder film formation. remove. It is preferable to use a solvent-soluble etching resist, because it is possible to selectively dissolve and peel only the resist, but other types of resist may be used, and suitable for the type at the time of peeling. Any peeling method may be used. After peeling off the unnecessary resist film, a mask for forming a thin film pattern with a photosensitive polymer film using a metal substrate as a support is completed through rinsing and drying processes.
In the method of manufacturing a mask for forming a thin film pattern by the photolithography method which is an embodiment of the present invention, the accuracy of the functional thin film pattern is almost the same as that of the photolithography method compared to the conventional photolithography method and the method using a metal mask. This man-hour is significantly less. In other words, it can be said to be a technology that can be widely applied to industrial applications as a method that satisfies both accuracy and man-hours. In addition, polymer films with different main solvents are used for processing the same substrate, and each process selectivity is used efficiently. It can be said that this is an epoch-making method that enables easy manufacturing.
[0015]
The material of the mask film is not particularly limited, and may be appropriately selected depending on the manufacturing method and other conditions. The photosensitive resin which is the mask coating resin used in the above photolithography method is preferably a polyimide resin from the viewpoints of the durability of the mask coating and the stability of the material. The polyimide resin film is coated with a varnish-like polyimide precursor on the support, semi-cured, and then subjected to pattern exposure to development, and then the polymer is dehydrated and closed by curing at ~ 400 ° C in a vacuum or non-oxidizing atmosphere. A polyimide film is formed. From the viewpoint of dimensional accuracy, the film thickness is preferably about 1 to 4 μm after curing, but when durability is important, there is no problem even if it is thicker than this. The polyimide precursor contains a cross-linking agent and can be handled in the same manner as a negative type photoresist that develops a cross-linking reaction by ultraviolet rays, and the resolution is about 1 to 10 μm. The polyimide coating is excellent in acid resistance and heat resistance, and is resistant to etching solution and developer. If the heating conditions are lower than the curing conditions after imidation, no outgas is generated, which is suitable without adversely affecting the film quality during film formation by vapor deposition or the like. Moreover, there is no problem if it is normally used even in an organic solvent such as acetone. The chemical resistance of the photosensitive polyimide film is effective for the durability of the novel mask of the present invention. A functional thin film is deposited on the mask surface every time it is used repeatedly, but if it is deposited excessively, the deposit will fall off as a foreign substance on the film formation surface, or the shape of the mask opening will be adversely affected. In order to prevent this, it is necessary to remove the functional thin film deposited on the mask according to the usage conditions. At that time, deposits can be removed by acid cleaning, and polyimide is acid-resistant so that shape change does not occur. That is, it can be said that it is an epoch-making structure that can be repeatedly used up to the corrosion resistance limit of the strength member without affecting the mask size and shape.
[0016]
In addition, depending on the dimensional accuracy required for the functional thin film shape and other conditions, a photosensitive resin such as acrylic, epoxy, or rubber that can be processed at a low temperature can be used. If it is a method other than the photolithography method, a non-photosensitive resin may be used as the mask film forming resin. In addition, silicon oxide, polycrystalline silicon, silicon nitride, alumina, glass, other ceramics, inorganic films such as fluorine compounds, and other precious metals such as gold, platinum, and silver, depending on the film thickness, strength, and other conditions Alternatively, a metal such as titanium or molybdenum may be used. However, when patterning the support by etching, the process selectivity of the support substrate and the corrosion dissolution, that is, the etching solution of the metal plate, the developing solution of the mask coating and the etching resist film, the mask coating and the etching resist insoluble in the stripping solution. Therefore, it is necessary to select as appropriate. Non-photosensitive resins are often cheaper than photosensitive resins. For those that do not require high accuracy, printing methods using non-photosensitive resins are used as appropriate. Can also .
Any member may be used for the support depending on the mask manufacturing method and other situations, such as a metal substrate or a plastic plate. However, the present invention uses a metal substrate. For metal substrates, When the substrate is patterned by etching, a metal plate such as cobalt / nickel / iron alloy, nickel / iron alloy, nickel / chromium / iron alloy is generally used. These materials may be appropriately selected from the coefficient of thermal expansion with the glass substrate for display devices, the material orientation required from the process, the manufacturing method, and other conditions. The thickness of the support is not particularly limited, but in the case of a metal substrate, about 50 to 150 μm is practical, and about 100 μm is particularly preferable from the viewpoint of strength and dimensional accuracy. With regard to the method of laminating the support and the mask coating, they can be easily bonded and integrated depending on the materials and types, but those with poor adhesion can be bonded by interposing an adhesive or by thermocompression bonding. That's fine.
When using an etching resist, the type and stripping method can be any method that can selectively strip away unnecessary etching resist without damaging the surface mask film and support. It may be.
[0017]
【Example】
Examples of use and manufacturing methods of the mask for forming a thin film pattern of the present invention will be described below using examples.
Example
Based on the drawings, an example of manufacturing a mask that is applied to pixel formation of RGB color light emitting materials in an organic EL display device, which is equivalent to a 10-inch diagonal as an effective display area, with a functional thin film pattern being formed as a flat panel display. This will be specifically described. First, the method of using the thin film pattern forming mask of the present invention is shown in FIG. Steps (A) to (C) correspond to A to C in FIG. (A) This shows a process of forming a functional thin film in a desired shape on a film formation substrate using the thin film pattern forming mask of the present invention. Reference numeral 1 denotes a functional thin film pattern forming mask, which is a mask having a laminated structure composed of a mask film 2 for forming a pattern of a functional thin film and a support 3 for the mask film 2, and (B) a film formation substrate. 5 is used by depositing the mask film 2 on the film. And it forms into a film-forming substrate from a support body side (upper part of a figure) by vacuum evaporation etc. (C) When the thin film pattern forming mask is separated from the film formation substrate after the film formation, the functional thin film 6 is formed only in the desired portion 4 along the pattern shape of the mask film. In this way, the functional thin film can be formed into a desired shape. In addition, if a thin film pattern forming mask is used repeatedly, a functional thin film is deposited on each part of the support surface, etc., so that the unnecessary functional thin film that has adhered is removed by cleaning as necessary, and the thin film pattern forming mask is repeatedly used. To use.
[0018]
Next, a photolithography method, which is a representative method for manufacturing the mask for forming a thin film pattern of the present invention, will be described. FIG. 2 is a flow sheet showing a manufacturing method when polyimide, which is a photosensitive resin, is used as a mask coating resin. Steps (A) to (H) correspond to A to H in FIG.
(A) A nickel iron alloy having a thickness of 100 μm was used as the support 3, and a polyimide precursor varnish of a photosensitive resin was applied to one surface of the support 3. The support used was pretreated beforehand such as degreasing. After the polyimide precursor varnish is applied, semi-cure (at 85 ° C. in air) is performed. By performing semi-cure, the solvent is volatilized by about 50 to 60% and semi-cured. (B) Then, a desired pattern is exposed on the semi-cured polyimide film 2 '. Since photosensitive polyimide behaves in the same way as negative resist, selective pattern exposure is performed so that the portion where the polyimide film is to be finally formed is exposed using the mask 7 and the portion where the polyimide film is to be opened is not exposed. Do. (C) After the exposure, a mask film 2 for forming a thin film pattern is formed on the metal substrate through steps such as development, rinsing, drying, and curing. Generally, the curing temperature of the polyimide film is raised stepwise and is preferably about 400 ° C. at maximum, and the curing conditions are appropriately set according to the resin used. Here, curing was performed in a vacuum atmosphere at a maximum of 350 ° C. Resin viscosity, concentration, application conditions, and the like were taken into consideration so that the polyimide film thickness after curing was 3 μm.
(D) Next, a metal substrate etching resist pattern is formed on the back surface side of the metal substrate 3. Before applying the resist, pretreatment such as degreasing was again performed on the metal substrate. Then, a solvent-soluble photoresist, here an AZ positive resist, was applied to the back side of the metal substrate 3, and prebaked to dry them. The prebaking temperature is generally about 80 to 90 ° C., and is set to 80 ° C. here. Then, a resist film 8 ′ is formed on the entire back surface on the metal substrate. (E) The metal substrate etching pattern is exposed there. Since the metal substrate is used as a support for the polyimide film for forming a functional thin film pattern, it was made to correspond to the pattern shape of the polyimide film, and patterning on the resist film utilized alignment exposure with the back surface. At the time of thin film formation, the mask film side is attached to the deposition target substrate such as glass, and the film is deposited from the metal substrate side by vacuum deposition or the like. The substrate opening must not be small. In addition, it is preferable that the opening of the metal substrate is not perpendicular to the vertical direction of the plate but has a mortar shape so that the opening gradually decreases toward the opening of the photosensitive polymer film. By adopting such a shape, a thin film can be deposited without unevenness, and the alignment accuracy of the front and back sides can be relaxed. (F) After the exposure, a patterned resist film 8 is formed on the back side through processes such as development, rinsing, drying, and post-baking (110 ° C.).
(G) Then, the metal substrate 3 on which the patterned photosensitive polymer film 2 and resist film 8 are formed on both surfaces is etched. A ferric chloride solution was used as an etching solution. On the surface side, since the photosensitive polymer functions as a resist, the portion of the metal substrate where the photosensitive polymer film is present is not corroded, and the portion where it is not present is corroded. On the back side, the metal substrate where the resist film exists is not corroded, but the part where the resist film does not exist is corroded. The resist pattern is a pattern corresponding to the surface side pattern, and an opening of the metal substrate corresponding to the opening of the photosensitive polymer film is formed and penetrates from the opening of the photosensitive polymer film toward the opening of the metal substrate. .
(H) Thereafter, only the unnecessary resist film 8 is peeled off with acetone. Since a solvent-soluble resist is used as the resist, when the mask is immersed in the solvent, only the resist on the back side of the metal substrate can be selectively removed. After removing the resist film, rinsing and drying are performed to complete a thin film pattern forming mask using a photosensitive polymer film having a laminated structure using the metal substrate of the present invention as a support.
[0019]
Comparative example
A nickel / iron alloy with a pressure of 0.08 mm is subjected to pretreatment such as degreasing and washing, and a resist is applied to both surfaces of the metal plate and prebaked. Then, a photomask is brought into close contact with the resist films on both sides to perform double-sided exposure. Next, the unexposed portion of the resist is removed through processes such as development, rinsing, drying, and post-baking, and then the exposed portion of the metal is etched by etching and patterned into an arbitrary shape. Finally, an unnecessary resist film was removed with a solvent or the like to form a single layer metal mask.
[0020]
Next, the dimensional accuracy of the mask for forming a thin film pattern of the example of the present invention and the metal mask of the comparative example will be compared. Table 1 relates to specific mask accuracy. The mask of the present invention shows the dimensional accuracy of the mask for forming a thin film pattern formed by a method combining the photolithography method and the etching described in the above embodiment, and the comparative example shows the dimensional accuracy of the pattern forming portion of the metal mask. It was. The functional thin film pattern formation using the thin film pattern formation mask of the embodiment utilizes the opening pattern of the mask film, and the support is not involved in the pattern formation.
[0021]
[Table 1]

[0022]
As apparent from Table 1, all of the short dimension, accumulated pitch error, and mask opening portion R are smaller in the example, and it is clear that a precise and precise mask with good dimensional accuracy can be formed. It was.
[0023]
【The invention's effect】
As described above, the mask for forming a thin film pattern according to the present invention is a novel mask having a cost advantage of a metal mask by a photoetching method and a lift-off shape and dimensional stability by a photolithographic method. Therefore, a highly accurate fine pattern can be formed easily, can be used repeatedly, is economically inexpensive, and has excellent effects in various aspects as compared with a conventional mask for forming a thin film pattern.
[Brief description of the drawings]
FIG. 1 is a process diagram of a method for producing a functional thin film using a mask for forming a thin film pattern of the present invention.
FIG. 2 is a process diagram of a method of manufacturing a mask for forming a thin film pattern by a photolithography method using a photosensitive polymer for the mask film of the present invention.
[Explanation of symbols]
1 Mask for thin film pattern formation
2 'mask coating (before patterning)
2 Mask coating (after patterning)
3 Support
4 Thin film pattern formation area (mask film opening)
5 Deposition substrate
6 Functional thin film
7 Mask
8 'resist film (before patterning)
8 Resist film (after patterning)

Claims (6)

A mask for forming a thin film pattern in which a mask film side of a mask for forming a thin film pattern is attached to a deposition target substrate, and a functional thin film having a shape corresponding to the opening pattern of the mask film is formed by sputtering or vapor deposition from the support side of the mask. In this manufacturing method, a photosensitive polymer film is formed on one side of a metal plate of a mask support, a mask coating pattern is exposed on the photosensitive polymer layer, and a development process and a curing process are performed on one side of the metal plate. A mask coating pattern of the cured polymer film is formed, and then a resist pattern for etching the metal plate corresponding to the mask coating pattern is disposed on the opposite surface of the metal plate of the mask support, and the mask coating and the resist coating are etched resist. As a result, etching is performed from both sides of the metal plate to form a through-hole corresponding to the coating pattern on the metal plate, Manufacturing method of the thin film pattern forming mask of laminated structure and removing the strike pattern.   A mask for forming a thin film pattern having a laminated structure, wherein the photosensitive polymer film formed on one side of the metal plate of the mask support according to claim 1 is a semi-cured photosensitive polyimide film semi-cured with a polyimide resin precursor. Manufacturing method.   2. The thin film pattern forming mask according to claim 1, wherein the photosensitive polymer film formed on one side of the metal plate of the mask support is a mask film made of an acrylic, epoxy, or rubber resin. Production method.   The laminated structure according to any one of claims 1 to 3, wherein an opening size of a mask film of each opening forming a pattern of a thin film pattern forming mask is smaller than an opening size of an opposing mask support. A method for manufacturing a mask for forming a thin film pattern.   5. The manufacturing method of a thin film pattern forming mask having a laminated structure according to claim 4, wherein the opening of the mask support for forming the pattern of the thin film pattern forming mask is gradually narrowed toward the mask film. Method.   A thin film pattern forming mask having a laminated structure manufactured by the manufacturing method according to claim 1.

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