Method for electrically connecting to a contact of a microelectronic component on a circuit board or substrate

A method is provided for making an electrical connection with a microelectronic component arranged on or embedded within a surface of a circuit board layer or a substrate. The microelectronic component has an electrical contact face that is accessible on a surface of the microelectronic component. An electrically conducting bump is applied to the electrical contact face of the microelectronic component. A metal foil or metal coat is applied via a coating of an insulating binder to the surface of the circuit board under an action of pressure and/or heat so that the electrically conducting bump penetrates the coating of the insulating binder to make the electrical connection between the metal foil or metal coat and the electrical contact face.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the priority of German Patent Application No: 10 2006 036 728.6, filed on Aug. 5, 2006, the subject matter of which is incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of Invention

The present invention relates generally semiconductor circuits, and more particularly to making an electrical connection to a contact of a microelectronic component on substrate or a circuit board.

2. Description of the Related Art

The integration of semiconductor components in circuit boards is assuming ever-increasing importance in the further development of circuit board production techniques.

For the production of highly integrated circuit boards, microelectronic components, such as semiconductor chips, SMD resistors, or SMD capacitors, are integrated in individual layers of circuit boards to increase the functionality of the circuit board. When integrating a semiconductor chip on a circuit board, the semiconductor chip is glued on a layer of the circuit board via, for example, a printed-on adhesive or an adhesive tape. The chip is then buried with an Resin Coated Copper (RCC) laminate, a layer of epoxy that is not fully cross-linked, and a copper foil. After lamination, the chip is covered by the epoxy of the RCC laminate. A space, which is also filled by the epoxy of the RCC laminate, separates the chip contacts and the copper foil. The copper foil and the epoxy over the chip contacts are then removed using a laser drilling machine and the micro holes thereby produced are filled using a current-less and/or galvanic metallization technique. After the electrical connection is made between the electric contacts of the chip and the copper foil, the copper foil is structured for producing printed board circuit tracks.

The depth of the micro holes produced with the laser drilling machine depends on the laminating parameters, the thickness of the semiconductor chip, and the thickness of the epoxy coat. This dependence means that the diameters of the micro holes do not drop below 50 μm at a depth of 25 to 50 μm. If the aspect ratio (ratio of diameter to depth) of the holes is undesirable, in particular less than 1:2, the metallization baths used may no longer adequately flow in and out of the holes and the metallization may be defective.

The copper foil is generally also strengthened during metallization. During the subsequent structuring of the copper foil into circuit tracks, this strengthening process has a negative influence on the width of the circuit tracks structure. the sub-surface etching, which affects the structure width, increases with the coat thickness. Hence, the thicker the copper coat, the larger the structures to be produced.

With the ever-increasing reduction in contact center-to-center distances (pitch) of the semiconductor chips, the limitations of the conventional micro-hole technology become more and more apparent. If the distance between two contacts on the chip becomes too small, the micro holes can no longer be produced while keeping adequate insulating distance between the contacts. This results in short-circuits between the contacts, rendering the product unusable. Problems using the conventional micro hole diameters, problems have already been arising at a pitch of less than 120 μm.

What is needed is a method for the electrical contacting of one or a plurality of microelectronic components on a substrate or a circuit board that avoids the disadvantages associated with the micro holes and can be implemented at low cost.

SUMMARY OF THE INVENTION

According to an embodiment of the present invention, a method is provided for making an electrical connection with a microelectronic component arranged on or embedded within a surface of a circuit board layer, the microelectronic component having an electrical contact face accessible on a surface of the microelectronic component, the method including applying an electrically conducting bump to the electrical contact face of the microelectronic component; and applying a metal foil or metal coat via a coating of an insulating binder to the surface of the circuit board under an action of pressure and/or heat so that the electrically conducting bump penetrates the coating of the insulating binder to make the electrical connection between the metal foil or metal coat and the electrical contact face.

According to another embodiment of the present invention, a method is provided for making an electrical connection with a microelectronic component arranged on or embedded within a substrate of a semiconductor chip, the microelectronic component having an electrical contact face accessible on a surface of the microelectronic component, the method including applying an electrically conducting bump to the electrical contact face of the microelectronic component; and applying a metal foil or metal coat via a coating of an insulating binder to the surface of the substrate under an action of pressure and/or heat so that the electrically conducting bump penetrates the coating of the insulating binder to make the electrical connection between the metal foil or metal coat and the electrical contact face.

In embodiments of the invention, the metal foil or the metal coat is connected via the electrically insulating binder to the surface of the substrate and an electrical connection is produced between the metal foil or metal coat and the electrical contacts of the microelectronic components. In one embodiment, the metal foil or metal coat is not applied to a substrate, i.e., it is separate or loose, or is only connected to a coat or layer of the insulating binder, e.g., in the form of an RCC laminate. The electrical, contacting is achieved by applying electrically conducting contacting bumps on the electrical contacts of the microelectronic components before connection to the metal foil or metal coat. As the metal foil or metal coat is pressed towards the substrate, the bumps penetrate the coat formed by the binder and make an electrical connection between the metal foil or the metal coat and the electrical contacts. In one embodiment, heat is also applied to the binder. The application of the electrically conducting contacting bumps, according to an embodiment, may take place before the microelectronic components are applied to the substrate or after the application or integration of these components to or in the substrate.

According to an embodiment of the invention, the electrical connection between the contacts of the microelectronic components, such as semiconductor chips or SMD components, and the metal foil or metal coat is achieved purely mechanically or via a soldered joint. In the case of a purely mechanical connection, the contact bumps are designed so that they form a shape that tapers upwards or has a plurality of studs, so that when the metal foil or metal coat is pressed on, the bumps penetrate the metal foil or metal coat. During the production of a soldered joint, the contacting bumps are selected from a solder which softens when the temperature rises, as is often necessary for producing the binding action of the binder, and attaches to the underside of the metal foil or metal coat. A thermoplastic or a duromer may be used as a binding agent. The melting point of the solder of the contact bump is set slightly higher than the setting temperature of the duromer. As a result, the laminating process alone also achieves the soldered joint between the metal foil and the contacts of the microelectronic components.

According to embodiments of the invention, the drilling of micro holes and their filling with an electrically conducting material is no longer required. The connection between the metal coat or metal foil and the electrical contacts of the microelectronic components is replaced by a soldered joint or a pressure contact. The method may be implemented at a lower cost, since there is no need for a laser drilling machine or the subsequent metallization of the micro holes. The strengthening of the metal coat or metal foil that often occurs in the metallization of the micro holes does not arise here, so that during the subsequent structuring, smaller structures can be etched from the coat. Thus, embodiments of the invention also allows smaller the contact center to center, since there are no limitations due to the production of the micro holes.

The electrically conducting contact bumps may be formed from different materials. For example, solder (even in the case of a purely mechanical connection), gold (e.g. au stud bumps), copper, nickel, or a mixture of nickel and diamond may be used as bumps. The metal foil or metal coat may be selected from copper. The connection of this metal foil or metal coat to the surface of the substrate may be achieved using various conventional methods. The binder may either be applied to the metal foil or metal coat and press on the substrate along with the metal foil or metal coat, or may alternatively be arranged on the substrate before the metal foil or metal coat is pressed towards the substrate. Conventional RCC laminate may be used in the binder.

In a further embodiment of the invention, a metal foil with a printed-on polymer is structured on the metal foil. Due to the structuring, the points on the metal foil which are to come into contact with the contact bumps are laid open and only the remaining points are covered with polymer or binder, which simplifies the contacting process since the contact bumps need not first penetrate the polymer material. Alternatively, a structured binder coat is applied to the substrate separately from the metal foil and the points at which contact bumps exist are released. The metal foil is then connected by the binder applied to the substrate during the connection process under the influence of pressure and temperature.

DETAILED DESCRIPTION

FIG. 1shows a cross-sectional view a semiconductor chip2having contacts that are to be electrically connected, arranged on a circuit board layer1is to be contacted, according to a first embodiment of the invention. According to this embodiment, the lower side of the semiconductor chip2is connected via an adhesive coat, not shown in the figure, to the surface of circuit board layer1. The contacts of semiconductor chip2are arranged on the upper surface of semiconductor chip2opposite the lower surface facing the circuit board layer1.

According to this embodiment, before semiconductor chip2is glued to circuit board layer1, a soldered bump3is arranged on the electrical contacts of the semiconductor chip2using conventional methods such as, e.g., template printing or dip soldering. In one embodiment, soldering material with a melting temperature of 220° may be used for the soldered bump3.FIG. 1shows the structure after semiconductor chip2is connected to circuit board layer1, the projecting soldering bumps3arranged visibly on the upper surface of the semiconductor chip2. Next, a layer of RCC laminate7, composed of a copper foil5and a polymer coat4, is laminated onto the surface of circuit board layer1and the semiconductor chip2. In one embodiment, the laminating process is carried out at a temperature of 200° C., as a result of which the polymer4of laminate7softens and flows around the semiconductor chip2, as well as the soldering bump3. As the soldering bump3is pushed through the softening polymer4, the temperature increases, causing the soldering bump3to become soft or liquid and connect to the underside of copper foil5. Thereafter, the structure is once again cooled down, causing the solder to solidify and create an electrical connection between the contacts of semiconductor chip2and copper foil5of laminate7.

FIG. 2shows a cross-sectional view of a design according to a further embodiment of the invention, in which, unlike the design shown inFIG. 1, a polymer coat8is arranged on copper foil5. Here, the polymer coat8initially applied to the whole surface is structured before the lamination process so that points6at which the copper foil5is to connect to the soldering bumps3are left uncovered or are only covered by a layer polymer coat that is thinner than the other regions. In this embodiment, soldering bumps3need penetrate no material coat or only a very thin layer of material coat during the connection process.

In a further embodiment of this process, as shown inFIG. 3, the polymer coat4and copper foil5are applied separately. In this embodiment, the connection between copper foil5and the soldering bumps3is made, similar to the previous embodiments, by the application of pressure and temperature during the laminating process.

FIG. 4shows a cross-sectional view of a design according to another embodiment of the invention in which the substrate is a semiconductor wafer9in which the semiconductor chips are integrated. In this embodiment, the soldering bumps3are first applied to the overlaying contacts of the semiconductor chips, as explained in reference to the previous embodiments. The process of connecting the contacts to a copper foil5is then carried out by laminating an RCC laminate7onto it, as previously discussed.

A further embodiment of the present method is illustrated in the cross-sectional view ofFIG. 5. In this embodiment, where semiconductor chips2have a greater thickness than the embodiments inFIGS. 1 to 3, circuit board layer1is provided with recesses in which semiconductor chips2are inserted. Before semiconductor chips2are glued into the circuit board layer1, semiconductor chips2are provided with soldering bumps3on their contacts as in the previous examples. The connection to the copper foil5of an RCC laminate7is again carried on as previously described.

In the embodiments described above, the electrical connection between the contacts of semiconductor chips2and copper foil5is made using a combination of pressure and temperature to produce a soldered joint between the two. In the following three embodiments, however, the electrical connection can be achieved purely mechanically, i.e., without the use of temperature. In these embodiments, the electrical contacts of semiconductor chips2are provided with electrically conducting contact bumps10, which taper upwards so that they can be forced into copper foil5.

FIG. 6shows a cross-sectional view of a design according to an embodiment of the invention, in which the studded contact bumps10arranged on top of the contacts of the semiconductor chips2are drilled into copper foil5by the epoxy of RCC laminate7, thereby making an electrical connection between the contacts of semiconductor ship2and copper foil5. In this and the next two embodiments the material of the electrically conducting contact bumps10are sufficiently hard to be able to be pressed into copper foil5. The use of a soldering material is not necessary in this embodiment.

FIG. 7shows two examples of further possible designs of contact bumps10for establishing an electrical connection to copper foil5. The left contact bump10ashown inFIG. 7has the shape of a so-called stud bump, while the right contact bump10bhas a multiplicity of small studs for penetrating the copper foil5. Such a surface structure, represented in a highly schematized manner in the figure, may be achieved by, for example, inserting diamond particles in a metallic material for producing the contact bump10. In an embodiment, this structure may be laminated as shown inFIG. 8. The penetration of contact bumps10in copper foil5is clearly seen in these two figures.

After the lamination and connection process, the copper foil5is structured on the surface in order to produce the corresponding circuit tracks.FIG. 9shows an example of a buried semiconductor chip2on a circuit board layer1connected to the copper foil5via the soldering bumps3. Also shown inFIG. 9are the adhesive coat11between semiconductor chip2and circuit board layer1, the electrical contact12of semiconductor chip2, and the structuring of copper foil5.

FIGS. 10a-10bshow two light-microscopic cross-section views of a connection of the soldering mass of soldering bumps3of semiconductor chip2and copper foil5in a structure such as that shown inFIG. 9. Here,FIG. 10bshows a greater magnification thanFIG. 10a. The soldered joint between contacts12and copper foil5can be clearly seen.

FIG. 11shows diagrammatically an example of the electrical connection of studded contact bumps10aover the buried semiconductor chip2, which establish a push button connection between contacts12of semiconductor chip2and copper foil5of the RCC laminate7. Here, the adhesive coat11between the chip2and the circuit board layer1, as well as the electrical contacts12of the semiconductor chip2can be seen.

FIGS. 12a-12bagain shows two light microscopic cross-sectional images of a buried contacted semiconductor chip2,FIG. 12bshowing a greater magnification thanFIG. 12a. The electrical connection between contact faces12of semiconductor chip2and copper foil5can also be clearly seen in these two Figures.

While the invention has been illustrated and described in detail in the drawings and forgoing description, such illustration and description are to be considered illustrative or and the invention is not restricted or limited to the disclosed embodiments. The different embodiments described above and in the claims can also be combined. Other variations to the disclosed embodiments can be understood and effected by those skilled in the art in practicing the claimed invention, from a study of the drawings, the disclosure and the appended claims.