JP2021028996A - Substrate for semiconductor device and semiconductor device - Google Patents

Abstract

To provide a substrate for a semiconductor device capable of mounting with good reliability even in a mounting substrate in which wiring is densely formed, and a semiconductor device using the substrate for a semiconductor device.SOLUTION: A substrate 1 for a semiconductor device has a metal part 11, which is at least an electrode part 11b, formed on a mother mold substrate 10. A recess 20 is formed in the mother mold substrate 10, and the metal part 11 is formed on the mother mold substrate 10 including the recess 20. A protruding part 11d is provided on a mother mold substrate side of the metal part 11, and only the protruding part 11d protrudes from the mother mold substrate side of the metal part 11.SELECTED DRAWING: Figure 2

Description

The present invention relates to a semiconductor device substrate in which leads are formed on the substrate, and a semiconductor device manufactured by using the semiconductor device substrate.

A conventional structure in which a semiconductor element is mounted on a substrate for supporting the semiconductor element, the semiconductor element and a metal terminal for external derivation are connected by wiring, and the entire substrate including the semiconductor element is covered with a protective material such as resin. Due to the structure of semiconductor devices, there is a limit to miniaturization. On the other hand, a metal portion to be a semiconductor element mounting portion or an electrode portion is formed, and after the semiconductor element is mounted on the metal portion and processing such as wiring is performed, the surface side of the metal portion having the semiconductor element or wiring is made of resin or the like. In the field of ultra-small semiconductor devices such as chip size, semiconductor devices that are sealed with the sealing material of the above and have a structure in which the metal part is partially exposed at the bottom can reduce the height to save space. The use is progressing.

In such a semiconductor device, mainly, a desired number of semiconductor device mounting portions and metal portions to be electrode portions are formed by plating (electrocasting) on a conductive mother die substrate, and the semiconductor element is formed. After sealing the surface side of the metal part that has been subjected to processing such as wiring with a sealing material, only the master substrate is removed, and a large number of semiconductor devices in an integrated state are individually separated. Manufactured via. As an example of a method for manufacturing such a semiconductor device, there is one disclosed in JP-A-2002-9196.

JP-A-2002-9196 Japanese Unexamined Patent Publication No. 2004-214265

Patent Document 1 discloses a semiconductor device configured so that when one or both of the back surface of a semiconductor element mounting portion and an electrode portion is resin-sealed, the semiconductor device is configured to slightly protrude (standoff) from the back surface of the sealing material. Has been done. By projecting the back surface of the semiconductor element mounting portion and the electrode portion from the back surface of the sealing material in this way, when the semiconductor device is mounted on the mounting substrate, the electrode portion (lead) of the semiconductor device and the electrode portion of the mounting substrate are used. Good bonding with (pad) can be achieved.

In recent years, in order to realize miniaturization of electronic devices, electrode portions and wiring portions of mounting substrates have been densely formed. However, in the structure of the semiconductor device, the entire back surface of the semiconductor element mounting portion and the electrode portion is sealed. Since it protrudes from the back surface of the stop material, the semiconductor element mounting portion (die pad) or electrode portion (lead) of the semiconductor device may come into contact with the electrode portion (pad) or wiring portion of the mounting substrate at an undesired location.

An object of the present invention is to partially project a protruding portion from the back surface of a metal portion to reduce the size of the obtained semiconductor device, and to reliably mount the semiconductor device on a mounting substrate formed by dense wiring. An object of the present invention is to provide a substrate for a semiconductor device capable of manufacturing a semiconductor device, and a semiconductor device manufactured by using the substrate for the semiconductor device.

In the substrate for a semiconductor device according to the present invention, at least a metal portion 11 serving as an electrode portion 11b is formed on the master substrate 10, and a protruding portion 11d that partially protrudes from the master substrate surface side of the metal portion 11 Is provided.

Further, a recessed portion 11e is provided on the surface of the metal portion 11 opposite to the surface side of the master substrate.

Further, the protruding portion 11d and the recessed portion 11e are provided at overlapping positions in the thickness direction of the metal portion 11.

Further, the protruding shape of the protruding portion 11d and the recessed shape of the recessed portion 11 are similar to each other.

In the method for manufacturing a substrate for a semiconductor device according to the present invention, at least a metal portion 11 to be an electrode portion 11b is formed on a master substrate 10, and the metal portion 11 partially protrudes from the master substrate surface side. A method for manufacturing a substrate for a semiconductor device provided with a protruding portion 11d, which is a step of forming a first resist layer 12 on a master substrate 10 and being covered with a first resist layer 12 of the master substrate 10. A step of forming a recess 20 in an unexposed region, a step of removing the first resist layer 12, a step of forming a second resist layer 16 on the master substrate 10, and a second resist of the master substrate 10. It is characterized by having a step of forming a metal portion 11 in an exposed region not covered by the layer 16 and a step of removing the second resist layer 16.

Further, in the step of forming the metal portion 11, the metal portion 11 is plated and grown on the surfaces of the master substrate 10 and the recess 20. Further, in the step of forming the metal portion 11, the metal portion 11 is plated and grown beyond the thickness of the second resist layer 16.

The semiconductor device according to the present invention has a metal portion 11 serving as an electrode portion 11b that is electrically connected to the semiconductor element 14, the semiconductor element 14 is mounted on the metal portion 11, and the semiconductor element 14 and the metal portion 11 are connected to each other. A semiconductor device that is electrically connected and sealed by a sealing material 19. The back surface of the metal portion 11 is exposed from the back surface of the sealing material 19, and the back surface of the metal portion 11 is covered with the sealing material 19. A projecting portion 11d formed so as to project from the back surface is provided, and the back surface of the metal portion 11 excluding the projecting portion 11d and the back surface of the sealing material 19 are substantially flush with each other.

Further, the surface of the metal portion 11 is provided with a recessed portion 11e.

Further, the protruding portion 11d and the recessed portion 11e are provided at overlapping positions in the thickness direction of the metal portion 11.

Further, the protruding shape of the protruding portion 11d and the recessed shape of the recessed portion 11 are similar to each other.

According to the present invention, only the protruding portion 11d is partially projected from the back surface of the metal portion 11, and the semiconductor device provided with the metal portion 11 has a mounting substrate in which electrodes and wiring are densely packed. However, easy, accurate, and reliable implementation is possible. Further, even if the diameter and width of the protruding portion 11d must be made smaller corresponding to the electrodes of the mounting substrate, the surface (surface area) of the metal portion 11 can be formed larger than that of the protruding portion 11d, and the metal portion 11 can be mounted. The degree of freedom in selection of the semiconductor element 14 can be expanded.

It is a partial plan view of the substrate for a semiconductor device which concerns on 1st Embodiment of this invention. It is sectional drawing and plan view of the substrate for a semiconductor device which concerns on 1st Embodiment of this invention. It is sectional drawing and bottom view of the semiconductor device which concerns on 1st Embodiment of this invention. It is a process explanatory drawing in the manufacturing method of the substrate for a semiconductor device which concerns on 1st Embodiment of this invention. It is a process explanatory drawing in the manufacturing method of the substrate for a semiconductor device which concerns on 1st Embodiment of this invention. It is a process explanatory drawing in the manufacturing method of the semiconductor device which concerns on 1st Embodiment of this invention. It is sectional drawing and bottom view of the semiconductor device which concerns on other Embodiment of this invention.

(First Embodiment)
Hereinafter, the semiconductor device substrate and the semiconductor device according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 6. As shown in FIG. 2, the semiconductor device substrate 1 according to the present embodiment is formed on a master substrate 10 made of a conductive material and the master substrate 10, and is manufactured by using this substrate. It is configured to include a metal portion 11 serving as an electrode portion 11b in the semiconductor device 70.

The base substrate 10 is made of a conductive metal plate (thickness of about 0.1 mm) such as stainless steel (SUS430, etc.), aluminum, copper, etc., and is a substrate for a semiconductor device 1 until it is removed in the manufacturing process of the semiconductor device. It is the main part of.

The metal portion 11 is made of a nickel alloy such as nickel, copper, or nickel-cobalt and is formed by plating. As shown in FIG. 1, one or a plurality of metal portions 11 are arranged on the surface of the master substrate 10. As one unit, it is formed in a form in which a large number of semiconductor devices to be manufactured are arranged in an aligned state.

A protruding portion 11d is formed on the surface side (back surface) of the master substrate of the metal portion 11. The protruding portion 11d is formed so as to partially protrude from the back surface of the metal portion 11. Further, a recessed portion 11e is formed on the surface of the metal portion 11 which is a surface opposite to the surface side of the master substrate, and more specifically, at a position directly above the protruding portion 11d. An overhanging portion 11c overhanging in the shape of an eave is formed at the upper end of the metal portion 11.

Most of the metal portion 11 is formed of, for example, nickel or a nickel alloy suitable for electrolytic plating, but the back surface side of the metal portion 11 can be appropriately soldered when mounting a semiconductor device. Therefore, a metal having good solder wettability, for example, a thin film 17 such as gold, silver, tin, palladium, or solder is arranged from the main material portion such as nickel. The thin film 17 can also be provided with a function of preventing erosion deterioration of the metal portion 11 by the etching solution when the master substrate 10 is removed by etching. The thickness of the thin film 17 is preferably about 0.01 to 1 μm.

Further, a surface metal layer 13 is formed on the surface of the metal portion 11. The surface metal layer 13 is formed as a plating film made of gold, silver, palladium, etc., which has excellent bondability with the electrodes of the semiconductor element 14, and has a predetermined thickness on the surface of the metal portion 11 by plating each master substrate 10. For example, in the case of gold plating, a thickness of about 0.1 to 1 μm is formed, and in the case of silver plating, a thickness of about 1 to 10 μm is formed.

Then, as shown in FIG. 3, the semiconductor device 70 manufactured by using the semiconductor device substrate 1 has an electrode portion 11b of the metal portion 11 in addition to the metal portion 11 obtained from the semiconductor device substrate 1. The configuration includes a semiconductor element 14 that is electrically connected to the semiconductor element 14 and a sealing material 19 that covers and seals the surface side of the semiconductor element 14 and the metal portion 11.

In the semiconductor device 70, the back surface side of the metal portion 11 is exposed as an electrode, a heat radiation pad, or the like on the bottom portion, and the protruding portion 11d is formed to protrude from the back surface of the exposed metal portion 11, and the metal excluding the protruding portion 11d is formed. The back surface side of the portion 11 and the back surface side of the sealing material 19 appearing as a part of the exterior of the device are located on substantially the same plane. On each surface of the semiconductor device 70 other than the bottom, only the sealing material 19 forming the exterior of the device appears (see FIG. 3B).

The semiconductor element 14 is a so-called chip in which a fine electronic circuit is formed, and an electrode provided on the surface of the semiconductor element 14 is directly bonded to the electrode portion 11b to electrically connect the semiconductor element 14 and the electrode portion 11b. It will be.

The sealing material 19 is a thermosetting epoxy resin or the like having high physical strength, and is sealed while covering the metal portion 11 and the semiconductor element 14, so that the structurally weak portion is isolated from the outside. It is a thing. When the semiconductor element 14 is a light emitting element such as an LED, a translucent material is used.

The encapsulant 19 has sufficient physical strength, fulfills a function of sufficiently protecting the inside as a part of the exterior of the semiconductor device 70, and peels off the master substrate 10 from the semiconductor device side. Even when it is physically removed by applying a force, the integrated state with the metal portion 11 is maintained without damage such as cracking.

Next, each step of the method of manufacturing the semiconductor device substrate and the method of manufacturing the semiconductor device using the semiconductor device substrate according to the present embodiment will be described.

As a manufacturing process of a substrate for a semiconductor device, first, a master substrate 10 is prepared, and a first corresponding to a recess 20 for forming a protruding portion 11d of a metal portion 11 (electrode portion 11b) on the master substrate 10. The resist layer 12 is arranged (see FIG. 4 (A)). Specifically, a photosensitive resist material is arranged on the surface side of the master substrate 10, and a mask film having a predetermined pattern corresponding to the formation position of the recess 20 (protruding portion 11d) is applied to the photosensitive resist material. In the mounted state, the first resist layer 12 is subjected to processing such as curing by exposure to ultraviolet irradiation and development to remove the resist agent in the non-irradiated portion, so that the formation position of the recess 20 (protruding portion 11d) is exposed. Form. The first resist layer 12 is formed of an insulating material having solubility resistance to an etching solution used when forming a recess 20 on the surface of the master substrate 10, and more specifically, an alkali development type photosensitive material. The sex resist material is closely arranged on the matrix substrate 10 so as to have a predetermined thickness, for example, a thickness in the range of 5 to 50 μm, or 20 μm in the present embodiment.

Subsequently, a recess 20 is formed in a region exposed from the first resist layer 12 of the master substrate 10 (see FIG. 4B). Specifically, the recess 20 is formed by etching the exposed region on the surface side of the master substrate 10 that is not covered with the first resist layer 12. The shape of the recess 20 may be circular or polygonal, and the depth of the recess 20 is preferably 5 to 30 μm. The method of forming the recess 20 is not limited to etching, and may be formed by laser processing or blasting.

Subsequently, the first resist layer 12 formed on the master substrate 10 is removed (dissolution removal, swelling removal) to obtain the master substrate 10 on which the recess 20 is formed (see FIG. 4C).

Subsequently, a second resist layer 16 for forming the metal portion 11 (electrode portion 11b) is disposed on the master substrate 10 (see FIG. 5 (A)). Specifically, a photosensitive resist material is arranged on the surface side of the master substrate 10, and a mask film having a predetermined pattern corresponding to the formation position of the metal portion 11 (electrode portion 11b) with respect to the photosensitive resist material. The film is cured by exposure to ultraviolet irradiation, developed to remove the resist agent in the non-irradiated portion, and the like so that the formation position of the metal portion 11 (electrode portion 11b) including the recess is exposed. Two resist layers 16 are formed. The second resist layer 16 is formed of an insulating material having solubility resistance to a plating solution used when forming the metal portion 11 and the surface metal layer 13, and more specifically, an alkali development type photosensitive member. The sex resist material is closely arranged on the matrix substrate 10 so as to have a predetermined thickness, for example, a thickness in the range of 10 to 80 μm, or 50 μm in the present embodiment. The first resist layer 12 and the second resist layer 16 are not limited to the photosensitive resist, and a paint that does not deteriorate with respect to the etching solution or the plating solution and can obtain a high-strength coating film is used as a base substrate. It can also be formed by coating so that the recess 20 and the arrangement portion of the metal portion 11 on the 10 are exposed so as to have a required coating thickness by electrodeposition coating or the like.

Subsequently, a metal portion 11 (electrode portion 11b) is formed in a region exposed from the second resist layer 16 of the master substrate 10 (see FIG. 5B). Specifically, degreasing, acid immersion, chemical etching, electrolytic treatment, strike plating, etc. are performed as plating pretreatments on the exposed region on the surface side of the master substrate 10 that is not covered by the second resist layer 16. After selection and application, a thin film 17 is plated and formed with a metal having excellent solder wettability, and a metal is laminated on the thin film 17 by plating (electrocasting) to form a metal portion 11 (electrode portion 11b). In this embodiment, the exposed region of the stainless steel matrix substrate 10 is chemically etched, and then a gold thin film 17 having a thickness of 0.01 to 1 μm is plated and grown, and then plated on the thin film 17 ( The metal portion 11 (electrode portion 11b) is formed by laminating nickel having a thickness of, for example, 20 to 100 μm, or 70 μm in the present embodiment, by electrocasting). The plating pretreatment is performed by selecting the materials of the master substrate 10 and the metal portion 11 (thin film 17), and the chemical etching in the master substrate 10 is performed by melting the master substrate 10 itself. The oxide film (inactive film) on the surface is removed, and the surface of the master substrate 10 becomes a rough surface. Further, the formation of the thin film 17 is not limited to before the main material portion of the metal portion 11 is formed by plating when the purpose is to prevent soldering of the semiconductor device, but after the completion of the semiconductor device 70 (matrix substrate). After removing 10), the thin film 17 may be formed by plating on the back surface of the metal portion 11 exposed from the sealing material 19.

Here, when the metal portion 11 is formed, the overhanging portion 11c is formed at the upper end portion of the metal portion 11 by plating growth exceeding the thickness of the second resist layer 16. Due to the presence of the overhanging portion 11c, when the sealing material 19 is used to seal the semiconductor device in the manufacturing process, the sealing material 19 is cured in a state where the overhanging portion 11c is difficult to be embedded. Even when the master substrate 10 is peeled off from the metal layer 11 and the sealing material 19, the metal portion 11 is surely contained in the sealing material 19 due to the biting effect between the sealing material 19 and the overhanging portion 11c. It remains and does not stick to and separate from the master substrate 10, and it is possible to prevent the metal layer 11 from being displaced or chipped. When the metal portion 11 is formed, if the plating grows within a range not exceeding the thickness of the second resist layer 16, a straight metal portion 11 having no overhanging portion at the upper end portion can be obtained.

Further, a protruding portion 11d that partially protrudes from a part of the back surface is formed on the back surface of the metal portion 11, and a recessed portion 11e is formed on the upper surface of the metal portion 11. The recessed portion 11e is formed directly above the protruding portion 11d, that is, at a position where the protruding portion 11d and the recessed portion 11e overlap in the thickness direction of the metal portion 11. This is because when the metal portion 11 is plated and formed, the metal constituting the metal portion 11 is a master mold including the bottom surface (inner surface) of the recess 20 which is an exposed region not covered by the second resist layer 16 of the master mold substrate 10. The protruding portion 11d is formed by plating growth from the surface of the substrate 10 and plating growth of the metal constituting the metal portion 11 in the concave portion 20, while the metal located directly above the protruding portion 11d (recessed portion 20). This is because the recessed portion 11e is formed on the surface of the portion 11 so as to follow the shape of the recessed portion 20. The protruding portion 11d and the recessed portion 11e are similar, that is, the protruding shape of the protruding portion 11d and the recessed shape of the recessed portion 11e are similar to each other, and the height dimension of the protruding portion 11d and the recessed portion 11e (recessed portion 20). The depth dimension of is in the relationship of the height dimension of the protruding portion 11d ≧ the depth dimension of the recessed portion 11e (recessed portion 20).

Subsequently, when the metal portion 11 having a desired shape is obtained, the surface metal layer 13 is formed on the surface of the metal portion 11 (electrode portion 11b) (see FIG. 5B). Specifically, a silver surface metal layer 13 having a thickness of 1 to 10 μm is plated on the surface of the metal portion 11 (electrode portion 11b). When the surface metal layer 13 is plated and formed, for example, when the metal portion 11 is made of nickel and the surface metal layer 13 is difficult to form in close contact with the surface metal layer 13, the surface of the metal portion 11 is formed in advance before the surface metal layer 13 is plated. It is desirable to perform base plating (copper strike, nickel strike, silver strike, or gold strike) to improve the adhesion of the surface metal layer 13 to the metal portion 11.

Subsequently, the second resist layer 16 formed on the master substrate 10 is removed (dissolution removal, swelling removal) to form a metal portion 11 (electrode portion 11b) on the master substrate 10 for a semiconductor device substrate. Is obtained (see FIG. 5 (C)). The metal portion 11 is formed on the surface of the master substrate 10 in a form in which one or a plurality of electrode portions 11b are arranged in an aligned state as many as the number of semiconductor devices to be manufactured, with one or a plurality of electrode portions 11b as one unit. In the present embodiment, the six electrode portions 11b are used as one unit.

Although the first resist layer 12 and the second resist layer 16 are formed on the front surface side of the master substrate 10, a resist layer may also be formed on the back surface side of the master substrate 10. The resist layer on the back side is a material that is resistant to the etching solution and plating solution in the cured state, and is a resist material that can be easily dissolved and removed when it is no longer needed, for example, alkali-developed type photosensitive with a thickness of about 50 μm. The film resist can be arranged by thermocompression bonding or the like, and can be cured and formed over the entire back surface of the film resist through treatments such as exposure by ultraviolet irradiation without a mask. The resist layer on the back surface side is not limited to the resist, and may be, for example, a cover film, in short, any one having solubility resistance and insulating properties.

Next, the manufacture of the semiconductor device using the obtained semiconductor device substrate 1 will be described. First, the semiconductor element 14 is placed on the electrode portion 11b (metal portion 11) of the semiconductor device substrate 1 and then mounted. The electrodes of the semiconductor element 14 and the corresponding electrode portions 11b (metal portions 11) are electrically connected (see FIG. 6A). This electrical connection is made by soldering. When mounting the semiconductor element 14, it is preferable that the electrodes of the semiconductor element 14 are electrically connected at a position avoiding the recessed portion of the electrode portion 11b (metal portion 11). Further, in the present embodiment, the semiconductor element 14 and the electrode portion 11b are electrically connected by a flip-chip method, but of course, a wire bonding method using a wire made of a conductive wire such as gold or copper is used. You may.

Subsequently, the surface side of the master substrate 10 is sealed with a sealing material 19 such as a thermosetting epoxy resin to put the semiconductor element 14 in a protected state isolated from the outside (see FIG. 6B). Specifically, an epoxy resin that serves as a sealing material 19 in the mold while mounting the surface side of the master substrate 10 on a mold mold that is an upper mold and allowing the master substrate 10 to play the role of a lower mold. Sealing was executed in the process of press-fitting, and on the master substrate 10, a large number of electrode portions 11b serving as one semiconductor device were uniformly sealed in an aligned state, and a large number of semiconductor devices were connected. It will appear in the state.

Subsequently, the master substrate 10 is removed to obtain a state in which the electrode portion 11b (metal portion 11) is exposed at the bottom of each semiconductor device (see FIG. 6C). To remove the master substrate 10 made of stainless steel, a method of physically peeling the master substrate 10 from the semiconductor device side to remove it is used. By using stainless steel having excellent strength and peelability for the master substrate 10, the master substrate 10 can be peeled off from the semiconductor device side and quickly separated and removed.

In addition, as a method for removing the master substrate 10, a method of etching (melting) the master substrate 10 can also be used. In the case of this etching, an etching solution having selective etching property is used so that the matrix substrate 10 is dissolved but the materials of the thin film 17 and the metal portion 11 are not affected. In the case of melting and removing, since an excessive force is not applied to the semiconductor device side, the probability of adverse effects due to the removal of the master substrate 10 can be reduced. When the base substrate 10 is removed by etching, it is desirable to form the thin film 17 prior to the formation of the metal portion 11 in order to obtain corrosion resistance.

At the bottom of the semiconductor device from which the master substrate 10 has been removed, the protruding portion 11d partially protrudes from the back surface side of the sealing material 19, and the back surface of the metal portion 11 excluding the protruding portion 11d and the sealing material 19 It is in a state where it is located on substantially the same plane as the back surface of. After removing the master substrate 10, if a large number of connected semiconductor devices are separated one by one, a finished product as one semiconductor device 70 can be obtained.

As described above, since the semiconductor device substrate 1 according to the present embodiment has the protruding portion 11d on the electrode portion 11b formed on the master substrate 10, the semiconductor device 70 using the semiconductor device substrate 1 Since a wiring escape structure can be obtained by forming a protrusion from the back surface of the sealing material 19 by the height dimension of the projecting portion 11d at the bottom portion, a desired mounting is performed as compared with a form in which the entire back surface of the electrode portion 11b is projected. It is possible to avoid contact / bonding of the electrode portion 11b other than the electrode portion and the wiring portion of the substrate, and it is possible to obtain a semiconductor device having excellent reliability. Further, since the protruding portion 11d is partially projected from a part of the electrode portion 11b (metal portion 11), the degree of freedom of mounting the semiconductor device on the mounting substrate can be increased.

Further, inside the semiconductor device 70, the upper end peripheral edge of the metal portion 11 is formed as an overhanging portion 11c in a substantially eaves-like shape, and the overhanging portion 11c is surrounded by the sealing material 19 in a sealed state by the sealing material 19. By being fixed (anchor effect), the overhanging portion 11c bites into the sealing material 19 which is firmly integrated with the resins, and acts as a resistor against an external force applied to the metal portion 11. Even if an external force that attempts to separate the metal portion 11 from the exterior of the device is applied to the back surface of the metal portion 11, such as when stainless steel or the like is used for the master substrate 10 and the master substrate 10 is physically peeled off from the semiconductor device side to remove it. The overhanging portion 11c hinders the movement of the metal portion 11, can eliminate the deviation of the metal portion 11 with respect to other parts, improve the yield at the time of manufacturing, and increase the strength as a semiconductor device during use. Durability and reliability of semiconductor device operation are also improved. Moreover, since the sealing material 19 enters the recessed portion 11e by having the recessed portion 11e on the surface of the metal portion 11, the sealing material 19 is sealed with the metal portion 11 in combination with the biting effect of the overhanging portion 11c. The adhesion with the material 19 can be further strengthened, the strength as a semiconductor device can be increased, and the protection of the semiconductor element 14 can be more reliably performed.

In the above embodiment, the shape of the protruding portion 11d includes a round shape, a circular shape, a polygonal shape, a spherical shape, a cone shape, and a pillar shape, and the boundary between the protruding portion 11d and the metal portion 11 (back surface) is It is preferable that the surface is formed so as to be a gently continuous surface. Further, in the above embodiment, the semiconductor element 14 is mounted on the electrode portion 11b, but a semiconductor element mounting portion may be provided as the metal portion 11 and the semiconductor element 14 may be mounted on the semiconductor element mounting portion. good. The adhesive material for mounting the semiconductor element 14 on the metal portion 11 (semiconductor element mounting portion, electrode portion 11b) includes solid, viscous, and liquid forms, for example, solder, silver paste, and the like. Examples include resin paste and die attach film.

Further, in the above embodiment, as shown in FIG. 3, by forming the metal portion 11 (electrode portion 11b) in a linear shape, the effective utilization area (metal portion) on the bottom portion (back surface of the sealing material 19) of the semiconductor device is formed. Since the area excluding the 11 forming area) can be maximized, the possibility of causing a problem can be reduced even if the wiring on the mounting board is complicatedly arranged. Further, as shown in FIG. 7, on the bottom portion (back surface of the sealing material 19) of the semiconductor device, one end of the metal portion 11 is arranged on the outer peripheral portion, and the other end of the metal portion 11 is concentrated on the central portion. If they are arranged, the arrangement interval of the adjacent metal portions 11 can be made constant. Such a configuration is effective when a large number of electrodes (electrodes of a mounting substrate) of the semiconductor element 14 are provided.

1 Substrate for semiconductor devices 10 Master substrate 11 Metal part 11b Electrode part 11c Overhanging part 11d Protruding part 11e Depression part 12 First resist layer 13 Surface metal layer 14 Semiconductor element 15 Wire 16 Second resist layer 17 Thin film 19 Encapsulant 20 Recess 70 Semiconductor device

Claims (7)

A substrate for a semiconductor device in which at least a metal portion (11) to be an electrode portion (11b) is formed on a master substrate (10).
A recess (20) is formed in the master substrate (10), and the metal portion (11) is formed on the master substrate (10) including the recess (20).
A protrusion (11d) is provided on the master substrate surface side of the metal portion (11), and only the protrusion (11d) is formed so as to protrude from the master substrate surface side of the metal portion (11). Substrate for semiconductor devices. The substrate for a semiconductor device according to claim 1, wherein the protruding portion (11d) is formed by providing a metal in the entire recess (20). The substrate for a semiconductor device according to claim 1 or 2, wherein a recessed portion (11e) is provided on a surface of the metal portion (11) opposite to the surface side of the master substrate. The substrate for a semiconductor device according to claim 3, wherein the protruding portion (11d) and the recessed portion (11e) are provided at positions where they overlap in the thickness direction of the metal portion (11). The substrate for a semiconductor device according to claim 3 or 4, wherein the protruding shape of the protruding portion (11d) and the recessed shape of the recessed portion (11e) are similar to each other. It has at least a metal portion (11) that serves as an electrode portion (11b) that is electrically connected to the semiconductor element (14), and mounts the semiconductor element (14), and the semiconductor element (14) and the metal portion (11) A semiconductor device that is electrically connected to and sealed with a sealing material (19).
The metal portion (11) is exposed from the back surface of the sealing material (19), and the back surface of the metal portion (11) is flush with the back surface of the sealing material (19).
A semiconductor device characterized in that only a protruding portion (11d) provided on the back surface of the metal portion (11) is partially projected from the back surface of the metal portion (11). The semiconductor device according to claim 6, wherein the protruding portion (11d) is made of metal.

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