The present application claims priority from Japanese patent application JP 2022-170683 filed on Oct. 25, 2022, the entire content of which is hereby incorporated by reference into this application.
The present disclosure relates to a film forming method for forming a metal film in a predetermined pattern on a surface of a substrate.
Conventionally, a metal film is formed by depositing metal on the surface of a substrate by electroplating (for example, JP 2016-125087 A). In JP 2016-125087 A, the film forming apparatus includes a housing containing a plating solution. The housing has an opening that is sealed with an electrolyte membrane. The film forming apparatus further includes a pressing mechanism that presses the substrate by the electrolyte membrane with a fluid pressure of the plating solution.
Here, when a metallic underlayer having a predetermined pattern is formed on the surface of the substrate, the film forming apparatus applies a voltage between the anode and the substrate while pressing the substrate with the fluid pressure of the electrolyte membrane. Thus, the film forming apparatus can form a metal film having the predetermined pattern on the underlayer. However, when an underlayer of the predetermined pattern is not formed on the substrate, it is also conceivable to use, for example, a masking material disclosed in JP 2016-108586 A.
Here, when a film is formed using a screen mask as the masking material, the screen mask is sandwiched between the substrate and the electrolyte membrane. In this condition, in order to ensure the adhesion between the substrate and the screen mask, the screen mask is pressed by the electrolyte membrane on which the fluid pressure of the plating solution is acting. However, the substrate includes an outer edge portion formed by an opposite surface facing the screen mask and a side surface. This may cause damage to the screen mask when pressed against the outer edge portion of the substrate.
The present disclosure has been made in view of the foregoing, and provides a film forming method for forming a metal film capable of, even when a screen mask is used, suppressing damage to the screen mask when pressed by the electrolyte membrane.
In view of the foregoing, the film forming method for forming a metal film according to the present disclosure is a film forming method, including: placing a substrate on a mount base; covering the substrate with a screen mask including a penetrating portion of a predetermined pattern; pressing the substrate by an electrolyte membrane with a fluid pressure of a plating solution contacting the electrolyte membrane via the screen mask; and applying a voltage between an anode contacting the plating solution and the substrate so as to allow metal ions contained in the plating solution to pass through the electrolyte membrane and form a metal film derived from the metal ions in the predetermined pattern on the substrate. The substrate includes an outer edge portion formed by an opposite surface facing the screen mask and a side surface. A cushion member is disposed along the outer edge portion before pressing the substrate.
According to the present disclosure, the cushion member is disposed along the outer edge portion of the substrate before pressing the substrate. Thus, when the substrate is pressed by the electrolyte membrane with the fluid pressure of the plating solution via the screen mask, the outer edge portion of the substrate is pressed by the screen mask via the cushion member. Consequently, damage to the screen mask can be suppressed by the outer edge portion of the substrate.
In one example of the present disclosure, in placing the substrate, the substrate may be housed in a recess of the mount base, the recess being formed for housing the substrate, and in disposing the cushion member, the cushion member may cover a gap formed between the side surface of the substrate and a side wall surface of the recess.
A gap may be formed between the substrate and the mount base with the substrate housed in the recess. With this gap formed, the screen mask easily enters the gap when the electrolyte membrane presses the substrate via the screen mask. Consequently, the screen mask contacts the opening edge of the recess, and the screen mask is easily damaged. In this example, by covering the gap with the cushion member, it is possible to prevent the screen mask from entering the gap. Consequently, damage to the screen mask can be suppressed.
In one example of the present disclosure, the cushion member may be attached to the screen mask, and in covering the substrate with the screen mask, the cushion member may cover the gap.
According to this example, since the cushion member is attached to the screen mask in advance, it is possible to prevent misalignment of the cushion member with respect to the screen mask. Furthermore, in covering the substrate with the screen mask, the cushion member can cover the gap at the same time.
In one example of the present disclosure, before placing the substrate, the cushion member may be attached to the substrate along the outer edge portion.
According to this example, the substrate can be placed on the mount base with the cushion member attached to the substrate. Therefore, when the substrate is placed, the cushion member can be disposed at the same time to prevent misalignment of the cushion member with respect to the substrate.
In one example of the present disclosure, the mount base includes the recess for housing the substrate, the cushion member may cover the side surface of the substrate by attaching the cushion member to the substrate, and in placing the substrate, the substrate may be housed in the recess while sandwiching the cushion member between the side wall surface of the recess and the side surface of the substrate.
According to this example, the substrate is housed in the recess of the mount base. At this time, the cushion member is sandwiched between the side surface of the substrate and the side wall surface of the mount base. This can suppress formation of a gap therebetween. Consequently, it is possible to prevent the screen mask from being damaged due to the gap between the substrate and the mount base. Furthermore, it is possible to prevent misalignment of the substrate with respect to the mount base.
In one example of the present disclosure, the mount base includes the recess for housing the substrate, the cushion member is attached to the side wall surface of the recess, and in placing the substrate, the substrate may be housed in the recess while sandwiching the cushion member between the side wall surface of the recess and the side surface of the substrate.
According to this example, the substrate is housed in the recess of the mount base. At this time, the cushion member is sandwiched between the side surface of the substrate and the side wall surface of the mount base. This can suppress formation of a gap therebetween. Consequently, it is possible to prevent the screen mask from being damaged due to the gap between the substrate and the mount base and to prevent misalignment of the substrate with respect to the mount base.
In one example of the present disclosure, a peripheral edge of the screen mask is fixed to a frame on a side adjacent to the electrolyte membrane, and in the frame, the screen mask may cover the substrate.
According to this example, the screen mask is supported by the frame on the side adjacent to the electrolyte membrane. Therefore, the screen mask can be pressed by the electrolyte membrane while suppressing deformation of the electrolyte membrane due to the fluid pressure of the plating solution. Furthermore, in the frame, since the screen mask covers the substrate, deformation of the screen mask caused by the pressure from the electrolyte membrane can be suppressed.
According to the present disclosure, even when the screen mask is used, it is possible to suppress damage to the screen mask when pressed by the electrolyte membrane.
First, a film forming apparatus 1 used in a film forming method for forming a metal film according to an embodiment of the present disclosure will be described.
As shown in
The film forming apparatus 1 includes a housing 15 containing the anode 11 and a plating solution L, a mount base 40 on which the substrate B is placed, and the mask structure 60. At the time of film formation, the mask structure 60 is placed on the mount base 40 together with the substrate B. The electrolyte membrane 13 is disposed between the mask structure 60 and the anode 11.
The film forming apparatus 1 includes a linear motion actuator 70 for raising and lowering the housing 15. In the present embodiment, for convenience of explanation, the electrolyte membrane 13 is disposed below the anode 11, and the mask structure 60 and the substrate B are further disposed below the electrolyte membrane 13. However, the positional relation is not limited to this as long as the metal film F can be formed on the surface of the substrate B.
The substrate B functions as a cathode. The substrate B is a plate-shaped substrate. In the present embodiment, the substrate B is a rectangular substrate. The substrate B has an opposite surface Ba facing the electrolyte membrane 13 (a screen mask 62) to serve as a film forming surface that functions as a cathode. The substrate B has a side surface Bb formed on an outer periphery thereof. The material of the substrate B is not particularly limited as long as the substrate B functions as a cathode (i.e., a conductive surface). Examples of the material of the substrate B may include a metal material such as aluminum or copper. When forming a wiring pattern using the metal film F, for the substrate B, a substrate having an underlayer of copper or the like formed on the surface of the insulating substrate made of a resin or the like may be used. In this case, after the metal film F is formed, the underlayer other than the portion on which the metal film F is formed is removed by etching or the like. In this way, a wiring pattern using the metal film F can be formed on the surface of the insulating substrate.
In one example, the anode 11 is a non-porous anode made of the same metal as the metal of the metal film. The anode 11 has a block shape or a flat plate shape. Examples of the material of the anode 11 may include copper or the like. The anode 11 dissolves when a voltage is applied by the power supply 14. However, when a film is formed using only metal ions of the plating solution L, the anode 11 is an anode insoluble in the plating solution L. The anode 11 is electrically connected to the positive electrode of the power supply 14. The negative electrode of the power supply 14 is electrically connected to the substrate B via the mount base 40.
The plating solution L is a liquid containing the metal of the metal film to be formed in the state of ions. Examples of the metal may include copper, nickel, gold, silver, iron, or the like. The plating solution L is a solution obtained by dissolving (ionizing) these metals with an acid such as nitric acid, phosphoric acid, succinic acid, sulfuric acid, or pyrophosphoric acid. Examples of the solvent of the solution may include water and alcohol. For example, when the metal is copper, examples of the plating solution L may include an aqueous solution containing copper sulfate, copper pyrophosphate, or the like.
The electrolyte membrane 13 is a membrane that can be impregnated with metal ions (i.e., can contain metal ions therein) together with the plating solution L when brought into contact with the plating solution L. The electrolyte membrane 13 is a flexible membrane. The material of the electrolyte membrane 13 is not particularly limited as long as metal ions of the plating solution L can move toward the substrate B when the power supply 14 applies a voltage. Examples of the material of the electrolyte membrane 13 may include a resin having an ion-exchange function such as a fluorine-based resin such as Nafion (registered trademark) available from DuPont. The film thickness of the electrolyte membrane 13 may be in the range of 20 μm to 200 μm. Specifically, the film thickness may be in the range of 20 μm to 60 μm.
The housing 15 is made of a material insoluble in the plating solution L. The housing 15 includes a storage space 15a for storing the plating solution L. The anode 11 is disposed in the storage space 15a of the housing 15. The storage space 15a includes an opening 15d on the side adjacent to the substrate B. The opening 15d of the housing 15 is covered with the electrolyte membrane 13. Specifically, the peripheral edge of the electrolyte membrane 13 is sandwiched between the housing 15 and a frame 17. Accordingly, the plating solution L in the storage space 15a can be sealed with the electrolyte membrane 13.
As shown in
The housing 15 includes a supply port 15b for supplying the plating solution L to the storage space 15a. Further, the housing 15 includes a discharge port 15c for discharging the plating solution L from the storage space 15a. The supply port 15b and the discharge port 15c are holes communicating with the storage space 15a. The supply port 15b and the discharge port 15c are formed with the storage space 15a interposed therebetween. The supply port 15b is connected to a liquid supply pipe 50. The discharge port 15c is fluidly connected to a liquid discharge pipe 52.
The film forming apparatus 1 further includes a liquid tank 90, the liquid supply pipe 50, the liquid discharge pipe 52, and a pump 80. As shown in
In the present embodiment, by driving the pump 80, the plating solution L is sucked from the liquid tank 90 into the liquid supply pipe 50. The sucked plating solution L is pressure-fed from the supply port 15b to the storage space 15a. The plating solution L in the storage space 15a is returned to the liquid tank 90 via the discharge port 15c. In this way, the plating solution L circulates in the film forming apparatus 1.
Further, by continuing the driving of the pump 80, the fluid pressure of the plating solution L in the storage space 15a can be maintained at a predetermined pressure by the pressure regulating valve 54. The pump 80 is for pressing the mask structure 60 by the electrolyte membrane 13 on which the fluid pressure of the plating solution L is acting. However, the pressing mechanism is not particularly limited as long as the mask structure 60 can be pressed by the electrolyte membrane 13. Instead of the pump 80, an injection device composed of a piston and a cylinder for injecting the plating solution L may be used.
In one example, the mount base 40 is made of a conductive material (e.g., metal). The mount base 40 includes a first recess 41 and a second recess 42. The first recess 41 is a recess that houses the substrate B. The second recess 42 is a recess for housing the mask structure 60 while the substrate B is housed in the first recess 41. In the present disclosure, the “recess” corresponds to the first recess 41.
The mask structure 60 includes a frame 61 and a screen mask 62. The screen mask 62 includes a penetrating portion 68 corresponding to the predetermined pattern P of the metal film F. The screen mask 62 includes a mesh portion 64 and a mask portion 65. The screen mask 62 is a flexible mask of about 50 μm to 400 μm in thickness. The screen mask 62 is supported by the frame 61 on the side adjacent to the substrate B.
The mesh portion 64 is fixed to the frame 61. The mesh portion 64 is stretched at a predetermined tension so as to cover the opening of the frame 61. The mesh portion 64 includes a plurality of openings 64c in a grid pattern. Specifically, as shown in
The mask portion 65 is fixed to a surface facing the substrate B of the surfaces of the mesh portion 64. The mask portion 65 includes a penetrating portion 68 corresponding to the predetermined pattern P. The mask portion 65 is a portion that comes into close contact with the substrate B at the time of film formation by the pressure from the electrolyte membrane 13. The material of the mask portion 65 is not particularly limited as long as the mask portion 65 can be brought into close contact with the substrate B. The mask portion 65 may be compressed and elastically deform by the pressure from the electrolyte membrane 13. Examples of the material of the mask portion 65 may include a resin material such as an acrylic resin, a vinyl acetate resin, a polyvinyl resin, a polyimide resin, or a polyester resin. The screen mask 62 having the predetermined pattern P can be manufactured by a general silk screen manufacturing technique using an emulsion. Therefore, a detailed description of a method of manufacturing the screen mask 62 will be omitted.
The frame 61 supports a peripheral edge 64d of the screen mask 62 on the side adjacent to the substrate B (the mount base 40). Specifically, the peripheral edge 64d of the screen mask 62 is fixed to the frame 61. In the present embodiment, the screen mask 62 has a rectangular outer shape. Accordingly, the frame 61 has a rectangular frame-like shape. The material of the frame 61 is not particularly limited as long as the frame 61 can retain the shape of the mask structure 60. Examples of the material of the frame 61 may include a metal material such as stainless steel, or a resin material such as a thermoplastic resin. The frame 61 is formed by punching a metallic plate, for example, and has a thickness of about 1 mm to 3 mm. Note that, for convenience of explanation, the thickness of the frame 61 is drawn to be thicker than the actual thickness in
The cushion member 30 is disposed along an outer edge portion Bc of the substrate B when the substrate B is pressed. The outer edge portion Bc is an edge (edge portion) formed by the opposite surface Ba of the substrate B facing the screen mask 62 and the side surface Bb of the substrate B.
Here, “the cushion member is disposed along the outer edge portion” as used herein may refer to the following cases (1) to (3). Specifically, in the case (1), the cushion member 30 is disposed along the outer edge portion Bc of the substrate B from the opposite surface Ba of the substrate B. The present embodiment and Modifications 1 to 3 described later correspond to the case (1). In addition, in the case (2), the cushion member 30 is disposed along the outer edge portion Bc of the substrate B from the side surface Bb. Modification 6 and Modification 7 described later correspond to the case (2). The case (3) includes the case (1) and the case (2). Modifications 4 and 5 described later correspond to the case (3).
As shown in
The cushion member 30 is made of an elastic material softer than the material of the substrate B. The material of the cushion member 30 is not particularly limited as long as damage to the screen mask 62 can be avoided. The cushion member 30 may be compressed and elastically deform by the pressure from the electrolyte membrane 13 (specifically, by the pressing of the cushion member 30). For example, the material of the cushion member 30 may be a rubber material such as silicone rubber (PMDS) or ethylene propylene diene rubber (EPDM). The hardness of the rubber material may be HS100 or less, specifically HS50 or less, in Shore A hardness. The “soft elastic material” is, for example, a material having a relatively low hardness measured by a hardness meter of a predetermined standard, and is a material having a low Young's modulus by a tensile test. In view of the adhesion between the mask portion 65 and the substrate B, the thickness of the cushion member 30 may be thinner than the thickness of the screen mask. The cushion member 30 may be made of a material softer than the material of the mask portion 65.
Referring to
At this time, as shown in
Next, the mask structure 60 is housed in the second recess 42 of the mount base 40, and the substrate B is covered with the screen mask 62. The cushion member 30 is sandwiched between the screen mask 62 and the opposite surface Ba of the substrate B. The cushion member 30 is also sandwiched between the screen mask 62 and the opposite surface 40a of the mount base 40.
Next, a pressing step S2 is performed. In this step, the substrate B is pressed by the electrolyte membrane 13 with the fluid pressure of the plating solution L contacting the electrolyte membrane 13, via the screen mask 62. First, the linear motion actuator 70 is driven. Accordingly, the housing 15 is lowered toward the mask structure 60 from the state of
Next, the pump 80 is driven. As a result, the plating solution L is supplied to the storage space 15a of the housing 15. Since the pressure regulating valve 54 is provided in the liquid discharge pipe 52, the fluid pressure of the plating solution L in the storage space 15a is maintained at a predetermined pressure. Consequently, as shown in
Here, as shown in
Further, when the pressing of the electrolyte membrane 13 is continued, as shown in
In the present embodiment, the cushion member 30 is disposed along the outer edge portion Bc of the substrate B before pressing the substrate B. Thus, when the substrate B is pressed by the electrolyte membrane 13 with the fluid pressure of the plating solution L via the screen mask 62, the outer edge portion Bc of the substrate B is pressed by the screen mask 62 via the cushion member 30. The cushion member 30 elastically deforms in the thickness direction and absorbs the pressing force of the screen mask 62. Consequently, the outer edge portion Bc of the substrate B can prevent the stress from being focused on the screen mask 62, and damage to the screen mask 62 can be suppressed.
In particular, a gap S may be formed between the substrate B and the mount base 40 while the substrate B is housed in the first recess 41. With this gap S formed, the screen mask 62 easily enters the gap S when the electrolyte membrane 13 presses the substrate B via the screen mask 62. Consequently, the screen mask 62 contacts the opening edge of the first recess 41, and the screen mask 62 is easily damaged. However, by covering the gap S with the cushion member 30, it is possible to prevent the screen mask 62 from entering the gap S. Consequently, damage to the screen mask 62 can be suppressed.
Next, a film forming step S3 is performed. In this step, a metal film F is formed while the pressing state by the electrolyte membrane 13 in the pressing step S2 is maintained. Specifically, a voltage is applied between the anode 11 and the substrate B. This allows metal ions contained in the plating solution L to pass through the electrolyte membrane 13. The metal ions passed through the electrolyte membrane 13 move through the exudation solution La to the surface of the substrate B, and the metal ions are reduced at the surface of the substrate B. Since the exudation solution La filled in the penetrating portion 68 is sealed inside the penetrating portion 68 by the electrolyte membrane 13, the metal film F having the predetermined pattern can be formed on the surface of the substrate B (see
Furthermore, since the exudation solution La is uniformly pressurized by the pressing of the electrolyte membrane 13, it is possible to form a homogeneous metal film F. After film formation, the plating solution L in the housing 15 is removed and the housing 15 is raised, such that the electrolyte membrane 13 is separated from the substrate B and the substrate B is pulled away from the mount case 40. In manufacturing a wiring pattern using the metal film F, a conductive underlayer formed on the surface of the insulating substrate B may be etched.
<Modifications>
As shown in
Hereinafter, the film forming method using the film forming apparatus 1 will be described. First, in the placing step S1, the substrate B is placed on the mount base 40. Specifically, the substrate B is housed in the first recess 41 of the mount base 40. Next, the cushion member 30 is disposed along the outer edge portion Bc of the substrate B. Specifically, the cushion member 30 covers the gap S from the screen mask 62 side (the electrolyte membrane 13 side). The substrate B is then covered with the screen mask 62. At this time, the frame 61 of the mask structure 60 is housed in the recess groove 43 of the mount base 40. Further, as shown in
In Modification 1 as well, as described above, damage to the screen mask 62 can be suppressed by the cushion member 30. In this Modification 1, the peripheral edge of the screen mask 62 is supported by the frame 61 on the side adjacent to the electrolyte membrane 13. Therefore, as shown in
As shown in
As shown in
Hereinafter, the film forming method using the film forming apparatus 1 according to Modification 2 and Modification 3 will be described. First, in the placing step S1, the substrate B is placed on the mount base 40. Specifically, the substrate B is housed in the first recess 41 of the mount base 40. In these modifications, the housing 15 is then lowered. Thus, the screen mask 62 covers the substrate B. At this time, the cushion member 30 is attached to the screen mask 62. Thus, the screen mask 62 can cover the opposite surface Ba of the substrate B and the cushion member 30 can cover the gap S. Further, since the cushion member 30 is attached to the screen mask 62 in advance, it is possible to prevent misalignment of the cushion member 30 with respect to the screen mask 62.
In Modification 2, the electrolyte membrane 13 is hardly deformed with the fluid pressure of the plating solution L. As a result, it is possible to suppress sagging or the like of the electrolyte membrane 13 due to repeated use.
As shown in
The mount base 40 includes the first recess 41 for housing the substrate B. Similar to the embodiment shown in
On the other hand, as shown in
Hereinafter, the film forming method using the film forming apparatus 1 according to Modification 4 and Modification 5 will be described. First, in the placing step S1, prior to placing the substrate B on the mount base 40, the cushion member 30 is attached to the substrate B along the outer edge portion Bc of the substrate B. As shown in
Further, as shown in
As described above, in Modification 4, since the gap S can be covered with the cushion member 30, the screen mask 62 can be prevented from being damaged. In Modification 5, since there is no gap between the substrate B and the mount base 40, the screen mask 62 can be prevented from being damaged.
In these modifications, the substrate B can be placed on the mount base 40 with the cushion member 30 attached to the substrate B. Therefore, when the substrate B is placed, the cushion member 30 can be disposed at the same time to prevent misalignment of the cushion member 30 with respect to the substrate B. Further, in Modification 5, the cushion member 30 is sandwiched between the side wall surface 41a of the first recess 41 and the side surface Bb of the substrate B. Consequently, it is possible to prevent misalignment of the substrate with respect to the mount base 40.
As shown in
In Modification 6 and Modification 7, the cushion member 30 is attached to the side wall surface 41a of the first recess 41. Specifically, as shown in
Hereinafter, the film forming method using the film forming apparatus 1 according to Modification 6 and Modification 7 will be described. First, in the placing step S1, the cushion member 30 is attached to the mount base 40 prior to placing the substrate B on the mount base 40. In these modifications, when the substrate B is placed, the substrate B is housed in the first recess 41 while sandwiching the cushion member 30 between the side wall surface 41a of the first recess 41 and the side surface Bb of the substrate B. Elastic deformation of the sandwiched cushion member 30 allows the substrate B to be secured to the mount base 40.
Further, in these modifications, by attaching the cushion member 30 to the side wall surface 41a of the mount base 40, the substrate B can be covered with the cushion member 30 from the side surface Bb of the substrate B along the outer edge portion Bc of the substrate B. Furthermore, since there is no gap S between the side surface Bb of the substrate B and the side wall surface 41a of the mount base 40, the screen mask 62 will not enter the gap. Consequently, the screen mask 62 can be prevented from being damaged.
In these modifications, when the substrate B is placed, the cushion member 30 can be disposed at the same time on the substrate B. Furthermore, it is possible to prevent misalignment of the cushion member 30 with respect to the substrate B and to prevent misalignment of the substrate B with respect to the mount base 40.
The present disclosure will be described by the following examples.
As the substrate for film formation, a glass epoxy substrate was prepared by impregnating a pile of glass fiber fabric with an epoxy resin. A copper foil was formed on the surface of the glass epoxy substrate. Next, a copper film was formed using the film forming apparatus according to the modification shown in
A copper film was formed in the same manner as in Example. The difference from Example was that the cushion member was not used.
Conditions of the electrolyte membranes according to the film forming apparatus of Example and the film forming apparatus of Comparative Example after film formation were checked. In both conditions of the two fluid pressures, the screen mask according to Example was not damaged. On the other hand, in both conditions of the two fluid pressures, the screen mask according to Comparative Example was broken.
While the embodiment of the present disclosure has been described above, the present disclosure is not limited to the film forming apparatus according to the above-described embodiment, and includes all aspects included in the concepts of the present disclosure and the claims. In addition, each configuration may be selectively combined as appropriate so as to achieve the above-described problems to be solved and effects. For example, shapes, materials, arrangements, sizes, and the like of the constituent elements in the above-described embodiment may be appropriately changed according to specific aspects of the present disclosure.
Number | Date | Country | Kind |
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2022-170683 | Oct 2022 | JP | national |