EP1500142A2

EP1500142A2 - Component

Info

Publication number: EP1500142A2
Application number: EP03714696A
Authority: EP
Inventors: Holger HÜBNER
Original assignee: Infineon Technologies AG
Current assignee: Infineon Technologies AG
Priority date: 2002-04-30
Filing date: 2003-03-12
Publication date: 2005-01-26
Also published as: US20050121801A1; WO2003094234A2; WO2003094234A3; US7335582B2; DE10219353B4; DE10219353A1; TWI245403B; RU2290718C2; RU2004134730A; TW200306660A

Abstract

The invention relates to a component, particularly a semiconductor component, comprising a first chip (10), which is placed on a second ship (20). The main surfaces (13, 23) of the first and second chips (10, 20) are respectively provided with first and second metallizations (12, 22) that face one another. First areas of the metallizations (12, 22) are provided for establishing an electrical connection between the first and second chip (10, 20). According to the invention, second areas of the metallizations (12, 22) are provided in the form of an additional electrical functional layer located outside of the first and second chips (10, 20).

Description

W ith honor

module

The invention relates to a component, in particular a semiconductor component, with a first chip, which is arranged on a second chip, and. in which the first and the second chip have an electrical connection to one another.

The arrangement of two chips one above the other and their electrical connection to one another is also referred to as "vertical circuit integration". One way to establish the electrical connection between the first and the second chip is to use bond wires. In this connection method, one of the two chips has a much larger footprint than the other. Each of the two chips has bond pads on its active main side, with the larger chip being located, for example, in an area on the edge, so that the smaller chip can be placed in the central area which is not provided with bond pads. Finally, the electrical connection is made by bond wires between respective bond pads.

Another possibility is to use conductive adhesive or solder balls to make the electrical connection. In both variants, the active main surfaces of the first and second chips face one another, so that respective contact surfaces come to lie opposite one another. Then point contacts are created using the conductive adhesive or the solder balls. Shear forces due to thermal stresses can therefore lead to impairment of the electrical contact.

The diameter of the bond pads or the contact areas in the variants described so far is between 70 to 100 μm. The distance between two bond pads or external contact areas is also in the order of magnitude mentioned. The provision of additional electrical functions in an electrical connection by means of bond wires, conductive adhesive or solder balls requires extensive design changes with regard to the arrangement of the first and second chips on one another, the electrical connection of individual bond pads or external contact areas.

An alternative connection method for establishing an electrical connection between the first and the second chip is the so-called “diffusion soldering method”. In this, the first and the second chip are arranged with their active main surfaces in relation to one another. On a respective active main surface there is a first or second metallization, which face each other. The first or second metallization can be in the form of a copper layer with a respective thickness of 1 to 5 μm. To establish an electrical connection between the first and second metallization, an additional thin solder layer, for. B. made of tin, with a thickness between 0.5 and 3 μm. The total thickness from the first or second metallization and the intermediate solder layer is typically less than 10 μm. In comparison to the joining methods mentioned at the beginning, an additional thin metal level is created here, which can be structured in a range of 1 μm due to its small thickness.

The object of the present invention is therefore to provide a component in which additional electrical functions can be implemented in a simpler manner.

This object is achieved with a component with the features of claim 1. Advantageous configurations result from the dependent claims.

The invention proposes a component, in particular a semiconductor component, with a first chip, which is arranged on a second chip, in which the first and the second Chip have first or second metallizations on one of their main surfaces, which face each other. First areas of the first or second metallization are provided for establishing an electrical connection between the first and the second chip. Second areas of the first and / or second metallization are provided as an additional electrical functional level outside the first and second chips.

The term "additional electrical functional levels outside the first and second chips" is to be understood such that the electrical functional level is not formed in the substrate of the first or second chip, but outside of it. The additional electrical functional level does not have to serve primarily for the electrical connection of the first and the second chip, but it can represent a structure that is independent of the first and the second chip. For example, it could be a passive structure that includes coils and delay lines.

The component therefore uses the diffusion soldering process described at the outset to establish an electrical connection between the first and second chips. In addition to the mere establishment of the electrical and mechanical connection, the existing metal layers are also used to perform further electrical functions. This allows the overall structure of the component to be implemented particularly cheaply and with high functionality. In particular, the component according to the invention enables a higher yield of chips per wafer, since the respective base areas of the first and second chips can be kept small due to the connection technology. Furthermore, the component according to the invention makes it possible to save one or more additional wiring levels and also ensures that the circuit levels in the first and second chips are shielded. This further electrical functional level is made possible by the fact that the metal layers used in a diffusion soldering process can be structured down to a range of 1 μm due to their small thickness. The structuring fineness is limited only by the choice of lithography, by the adjustment accuracy of the tool that places the first and second chips one above the other, and by solder squeezing. With a conventional proximity lithography, structures of up to 3 to 5 μm can be resolved. The contact lithography, which is also frequently used, even enables structures of up to 1 to 2 μm. If you accept a longer adjustment time for positioning the first and second chips one above the other, an accuracy of 1 μm can also be achieved here. Solder squeezing in the range of 1 to 2 μm is inevitable in principle, but can be avoided by using further measures. For example, the first and second metallizations coated with a solder can be made 1 to 5 μm larger than the solder to be applied thereon. The solder squeezes are thereby caught, but a lower degree of structuring fineness is achieved.

The first and / or second metallization are expediently connected via contact material elements to contact pads located in an uppermost metallization layer. The top metallization layer is located within the substrate of a respective chip. It represents the circuit level closest to the active main area, the active main area being a main page of a chip. In contrast to conventional arrangements, in which the contact pads are located in the uppermost metallization layer, that is to say in the "interior" of the chip and can be contacted directly, for example via bond wires or solder balls, the first and / or second metallization is directly on the respective main surface of the first or second chips. In contrast to conventional arrangements, the electrically connected contact pads do not have to be directly opposite.

The additional electrical functional level outside of the first and second chips consequently provides an additional metal layer as a further wiring level.

The first or second chip preferably has no metallization at the points at which the opposite chip has second areas of metallization, so that the second areas can assume an electrical function for the operation of the opposite chip. The further wiring level is thus directly between the first and second chip. To avoid short circuits, a corresponding “window” is therefore left free on one of the main surfaces of the opposite chips.

In a further embodiment of the invention, the first chip can have different sizes, whereby it can be smaller, the same size or larger than the second chip. The second chip has second areas of the second metallization at least outside of an overlap area which is formed between the smallest first chip and the main area of the second chip. The second areas of the second metallization located outside the overlap area can advantageously be used as coding.

It is preferred if the second regions of the second metalization can be contacted by the first metalization of the first chip when a larger first chip is arranged on the second chip. The second areas of the second metallization thus preferably consist of two metal surfaces which initially have no electrical connection to one another. If these two metal surfaces lie outside the overlap area between the first and second chip, the connection remains open. The arrangement of a larger one However, the first chip on the second chip can result in a connection of the two metal surfaces, as a result of which the second chip receives information about the size or type of the first chip.

In another embodiment, the second regions of the second metallization can also enable coding after the first chip has been arranged on the second chip by separating or connecting conductor tracks or metal surfaces that are part of the second regions. The second areas must then be located outside the overlap area between the first and second chips. The electrical connection of conductors in the second areas can be done by subsequently applied conductive material, eg. B. a solder or conductive adhesive. The electrical connection between two conductor tracks could be separated, for example, by means of a laser.

The second regions of the first and / or second metallizations preferably comprise test pads which are located within the overlap region of the first and second chips. As long as the first and second chips are not yet connected to one another, the test pads are freely accessible. However, after the first and second chips have been joined together, access is no longer possible since the test pads are then located within the overlap area of the first and second chips.

The test pads on the first or second chip are preferably brought into mechanical contact with second regions of the metallization of the opposite chip after the first chip has been arranged on the second chip. In accordance with the procedure for establishing an electrical connection, the test pads are connected to a metallization on the opposite chip via a solder layer. In this case, the metallization on the opposite chip preferably has no electrical function. This pre go allows a stable mechanical connection between the first and second chip, without the use of another connecting means, such as. B. an adhesive.

Accordingly, all immediately opposite second areas of the first and second metallization also serve for the mechanical fastening of the first and second chips. The second areas should therefore, if possible, be made flat in the overlap area between the first and second chips.

Preferably, the opposing second regions serving for mechanical fastening are designed in the form of a ring surrounding the first regions of the first and second metallization. As a result, the first areas of the metallization lying inside the ring are hermetically sealed and protected against corrosion by moisture. The corrosion resistance of the surfaces can also be improved by subsequently dip-gilding the component.

The invention is described in more detail with reference to the following figures. Show it:

FIG. 1 shows a component in cross section before connecting a first and second chip using a diffusion soldering process,

FIG. 2a shows the top view of a second chip, in which parts of the metallization are used as a further wiring level,

FIG. 2b shows a sectional view of the arrangement from FIG. 2a,

FIG. 3a shows an exemplary embodiment in which second areas of the metallization are provided for coding,

FIG. 3b shows a sectional view of the arrangement from FIG. 3a, FIG. 4 shows a further exemplary embodiment in which the second areas of the metallization are provided as coding,

FIG. 5 shows a cross section through the component in which the second regions of the metallization are designed as bond pads,

FIG. 6 shows a cross section through the component in which the second regions of the respective metallizations are designed as test pads,

7a, b each show a cross section through the component, in which the second regions of respective metallizations are formed as strip lines, and

Figure 8 is a plan view of the component in which the second regions of the metallization are designed as a closed ring.

FIG. 1 shows in cross section a component before connecting a first chip 10 to a second chip 20 using a diffusion soldering process. The first chip 10 and the second chip 20 each have, for example, a contact pad 11 or 21 on their active main surface 13 or 23, which is located in the uppermost metal layer of the chips 10, 20.

The first chip 10 has a first metallization 12 on its active main surface 13. The metallization 12 is divided into areas that are electrically separate from one another. In the figure, one of these areas is electrically connected to the contact pad 11 via a contact material element referred to as a via 14. The essential characteristic of the diffusion soldering method is that an area of the first metallization 12 connected to the contact pad 11 has a substantially larger area. In a corresponding manner, a second metallization 22 is formed on the active main area 23 of the second chip 20. This is also divided into electrically separated areas. In the figure, one of these areas is connected to the contact pad 21 via a via 24.

Those areas of the first and second metallization 12, 22 which have an electrical connection to bond pads 11, 21 and are later to be electrically connected to one another are referred to below as first areas of the respective metallization.

The first and second metallizations 12, 22 usually consist of copper and each have a thickness of approximately 1 to 5 μm. A further metal layer 30 is applied to one of the metallizations 12 or 22, which layer consists for example of tin and has a thickness between 0.5 and 3 μm.

The regions formed in the first and second metallizations 12, 22 are normally configured identically, so that they are assigned to one another when the first chip 10 is adjusted above the second chip 20. This results in a large-area connection level, as a result of which the first and second chips 10, 20 are connected to one another in a stable manner.

While in the arrangements known from the prior art, the metallizations are only used to produce an electrical and / or mechanical connection, the invention provides for areas of the metallization to be used as an additional electrical functional level, which is located outside the first and second chips ,

FIG. 2a shows a first embodiment in a top view. A section of the second chip 20 is shown, which is also referred to as a bottom chip. The second me- Tallization 22 has first areas 22a, which are provided for establishing an electrical connection between the bottom chip 20 and the first chip or top chip 10 shown in Figure 2b. For example, the first area 22a is configured in a ring shape. In a recess 25 of the first area 22a of the second metallization 22, second areas 22b are provided, which are designed in the form of conductor tracks. As can be seen better from FIG. 2b, the top chip 10 has no metallization in this area. The second regions 22b thus represent an additional wiring level on the active main surface 23 of the bottom chip 20. Accordingly, the second regions 22b have a connection to the contact pads 21 via plated-through holes 24.

The use of the metallization as a further wiring level is only possible because the metallizations can be structured in a range of up to 1 μm due to their small thickness. In such a configuration, it is useful to avoid short circuits if a corresponding window is left free in the metal layer on the opposite chip side. This expediently has the dimensions of the recess 25 in the second metallization 22a.

It can also be clearly seen from FIG. 2b that the contact pads 11, 21 are offset from one another. An opposing arrangement is not necessary since the electrical connection via the metallizations 12, 22 allows the contact pads 11, 21 to be in any position.

FIGS. 3a and 3b show a further exemplary embodiment in which the second regions of a metallization are used for coding. FIG. 3a shows a top view of the component according to the invention. On the bottom chip 20 is a top chip 10 (solid line) or alternatively a somewhat larger top chip 10 '(the one around the dashed area compared to the chip 10 is applied). The second regions of the metallization 22 are applied in the form of two metal surfaces. These metal areas or second areas of the metallization 22 lie outside an overlap area when the smaller top chip 10 is applied to the bottom chip 20. If, on the other hand, the larger top chip 10 'is provided for connection to the bottom chip 20, the second area 22 lies within the overlap area of the two chips. The top chip 10 ′ then preferably has an area 12 ′ in the metallization 12, so that an electrical connection is established between the two metal surfaces of the second metallization 22. In this way, the bottom chip 20 is able to recognize whether it is a top chip 10 or a top chip 10 '.

This application is particularly interesting when the bottom chip 20 and the top chip 10, 10 'are of different types. For example, one of the two chips could be a processor chip, while the other represents a memory. The component can then be assembled outside of the wafer production. This procedure saves expensive embedded processes. In particular, e.g. B. a processor with different sized memories can be assembled without having to change even a single lithography mask.

A bottom chip 20 embodied as a processor chip could identify the memory chip 10, 10 ′ to which it was connected simply by “querying” the area size of the top chip. For this purpose, second areas of the second metallization are provided on the bottom chip outside the surface edge of the smallest top chip 10, which are contacted by a corresponding bridge (metalization 12 ′) when a larger top chip is placed on it. Such coding could of course also take place within the chip area of the smaller top chip 10. In general, corresponding contact areas and bridge combinations can be used to implement general coding functions based on the pattern of conventional jumpers, with the contact areas and bridges optionally being located both on the bottom chip and on the top chip.

For example, by leading out conductor tracks 26 beyond the surface edge of the top chip 10, coding can also be carried out on the finished component. To do this, only the corresponding connections, e.g. B. with a laser, are severed (isolation area 28) or corresponding conductor tracks with a Verbindungselernent 27, z. B. a conductive adhesive or solder. Such a variant is shown in FIG. 4.

Likewise, discrete components such. B. resistors or capacitors are applied to the bottom chip 20 and connected to the conductor tracks 26.

Figure 5a shows a further embodiment of the component according to the invention in cross section. In this exemplary embodiment too, the bottom chip 20 is larger than the top chip 10. In the area outside the overlap area, a large-area metallization 22 is provided, which is connected to a contact pad 21 via a via 24. The small contact pad in the uppermost metallization layer thus leads to a large contact area. This contact area can have an area of 100 × 100 μm ² . This freely accessible metal surface can be used for another

Contacting with a bond wire can be used. The surface of this freely accessible metallization surface 22 is preferably gold-plated.

This variant creates the possibility that no bond areas have to be provided in the area of the uppermost metallization layer in a chip. The bond areas are Realized on the main surface of the chip only at the time of preassembling and connected to the integrated circuit via small vias with a diameter of approximately 1 μm square. As a result, the chip area can be reduced, which increases the yield on a wafer. In addition, the area of this bond metallization can be greatly increased compared to a conventional method.

FIG. 6 shows a further exemplary embodiment, in which the top chip 10 has a test pad 100 which is connected to a contact pad 11 via a via 14. The test pads are only required during the production of a chip to check the functionality. After the correct functionality has been determined, access to these test pads is no longer necessary. According to the invention, the test pad 100 is connected to a metallization 201, which is part of the second region of the second metallization of the bottom chip 20, whereby the two chips are stably attached to one another. In a corresponding manner, a test pad 200 is provided on the main surface of the bottom chip 20, which is connected to a metallization 201 - likewise without electrical function - in the metallization 12 of the top chip 10.

Compared to the arrangements known from the prior art, no additional area is required for the test pads. Just like the contact pads from FIG. 5a, the test pads 100, 200 are only realized by means of the first or second metallization. It is particularly advantageous to place these areas in the area of the smaller top chip 10. The test pads are thus used after the test for the mechanical connection of the chips, especially since a large part of the areas outside the first areas of the metallizations are used as "dummy areas" only for mechanical connection and heat dissipation. Some of these existing areas will therefore become the chip in addition to the function test used. The testing should advantageously be carried out on the entire wafer after the respective metallizations have been applied and structured. After the test, the wafer containing, for example, the second chips can be tinned in the electroless immersion bath, only the open metallizations being coated with the necessary thin solder layer. The chips are thus manufactured in the so-called "front end". This is followed in the "preassembly" by the preparation of the bond pads, the circuit tests as well as the tinning and vertical integration, ie the connection of the first and second chip. Afterwards the assembly in the housing takes place in the "backend". The circuit test is thus integrated in the process flow of assembly technology.

In general, the diffusion soldering process strives to achieve a connection of the two chips that is as large as possible since good heat conduction and good mechanical contact are desired. For this purpose, those second areas of the metallization that have no electrical function are left as dummy surfaces. However, these areas can advantageously also be used as shielding in order to electrically decouple the circuits in the first and second chips from one another. This becomes necessary in particular with the increasing operating frequencies and switching speeds.

FIG. 7a shows an exemplary embodiment in which the second regions of the metallizations are designed as coplanar strip lines or in connection with one or the two uppermost metal levels of the chips as normal strip lines (FIG. 7b). This variant is interesting for input / output lines of high-frequency circuits.

In the exemplary embodiment in FIG. 8, the second region of the metallizations 12, 22 is formed in a ring around the first regions of the metallizations 12, 22. The closed metal ring closes the first areas of the Metallized contacts hermetically prevent corrosion from moisture. The corrosion resistance of the surfaces can also be improved by subsequently dip-gilding the component.

Reference character list

10, 10 'chip

11, contact pad

12, 12 'metallization

13 active main area

100 test pad

101 metallization (without electrical function)

20 chip

21 bondpad

22 metallization

22a, 22b metallization

23 active main area

24 plated-through holes

25 recess

26 ladder train

27 connecting element

28 Isolation area

200 test pad

201 metallization (without electrical function)

30 metal layer

Claims

claims

1. Component, in particular semiconductor component, with a first chip (10) which is arranged on a second chip (20), in which the first and the second chip (10, 20) each on one of their main surfaces (13, 23) first or have second metallizations (12, 22) which face each other, first regions of the metallizations (12, 22) being provided for establishing an electrical connection between the first and second chips (10, 20) and second regions of the metallization (12, 22) are provided as an additional electrical functional level outside the first and second chips (10, 20).

2. Component according to claim 1, so that the first and / or second metallization (12, 22) are connected via contact material elements (14, 24) to bond pads (11, 21) located in an uppermost metallization layer.

3. Component according to claim 1 or 2, characterized in that the first or second chip (10, 20) at the points at which the opposite chip (20, 10) has second regions of the metallization (12, 22) has no metallization, so that the second areas can assume an electrical function for the operation of the opposite chip (20, 10).

4. Component according to one of the preceding claims, characterized in that the first chip (10) can have different sizes, the first chip (10) being smaller, the same size or larger than the second chip (20) and the second chip (20) at least outside of an overlap area between the smallest first chip (10) and the main surface of the second Chips (20) is formed, has second regions of the second metallization (22).

5. The component according to claim 4, so that the second regions of the second metallization (22) can be contacted by arranging a larger first chip (10) on the second chip (20) through the first metallization of the first chip (10).

6. The component according to claim, so that the second regions of the second metallization (22), after arranging the first chip (10) on the second chip (20), enable coding by separating or connecting conductor tracks of the second regions.

7. The component according to one of the preceding claims, that the second regions of the first and / or second metallization (12, 22) comprise test pads which are located within the overlap region of the first and second chips (10, 20).

8. The component according to claim 7, dadurchgekennz ei chnet that the test pads on the first or second chip (10, 20) after arrangement of the first chip (10) on the second chip (20) in mechanical contact with second areas of metallization of the opposite Chips are brought.

9. Component according to one of the preceding claims, dadurchgekennz ei chnet that immediately opposite second regions of the first and second metallization (12, 22) serve for mechanical fastening of the first and second chips (10, 20).

10. The component according to claim 10, d a d u r c h g e k e n n z ei c h n e t that the opposite, for mechanical fastening second areas in the form of a surrounding the first areas of the first and second metallization (12, 22)

Ring are formed.