JP2000294722A - Laminated chip semiconductor device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To relax geometrical restrictions upon chip lamination. SOLUTION: The semiconductor device includes first and second chips 1 and 2, a rear side of the first chip 1 opposed to a rear side of the second chip 2, and electrodes formed on front sides of the first and second chips 1 and 2. Such a multilayered chip having chips opposed at their rear sides can remove geometrical restrictions of arrangement relating to a wiring structure. It is preferable that a junction material 3 be disposed between the rear sides of the first and second chips 1 and 2 and have an insulating property. A front surface of one of the both chips 1 and 2 is joined to an interposer 4, and the interposer 4 has a surface to which a printed wiring board is joined.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a stacked chip semiconductor device, and more particularly, to a stacked chip semiconductor device of a chip stack type package in which a plurality of chips are stacked.

[0002]

2. Description of the Related Art In order to avoid an increase in the mounting area, a package having a stacked structure in which chips are stacked is used. The package is mounted face-up on an interposer including a printed circuit board. There is also known a packaging called a chip stack type package which is similarly stacked face-up on a surface of the device and mounted. In such a known package, as shown in FIG. 4, a metal wiring layer 02 as an interposer is bonded to an upper surface of a tape base material 01 as an interposer, and a first mount is provided on an upper surface side of the metal wiring layer 02. The first chip 04 is mounted via the material 03, and the second chip 05
It is mounted on the upper surface side of the first chip 04 via the mounting material 06. When the two chips 04 and 05 are overlaid, the electrode pads 07 of the first chip 04
The second chip 05 must be smaller in size than the first chip 04 so as not to be obscured by the metal pads 08 and bonded to the electrode pads 07.

[0003] Such known packages, in which the electrical connection between the electrode pads and the metal wiring layers uses metal wires for both chips, are limited in their structure. In particular, the electrode pads 07 of the first chip 04
There is a restriction that the second chip 05 must be smaller than the first chip 04 in order not to be hidden by the chip 05.

[0004] It is desired that restrictions on the structure of the stacked mounting be relaxed. Furthermore, it is preferable that there are few restrictions on the combination of a plurality of chips and that the mounting density be improved.

[0005]

SUMMARY OF THE INVENTION An object of the present invention is to provide a laminated chip semiconductor device capable of alleviating the structural restriction of lamination. Another object of the present invention is to provide a laminated chip semiconductor device which can reduce the restrictions on the structure of lamination mounting, reduce the restrictions on the combination of a plurality of chips, and improve the mounting density. .

[0006]

The laminated chip semiconductor device according to the present invention comprises a first chip (1) and a second chip (2), the back side of the first chip (1) and the second chip. The back side of (2) faces, and electrodes are formed on the front side of the first chip (1) and the second chip (2). The multilayer chip having such a back-facing arrangement is released from the geometrical restriction of the arrangement with respect to the wiring structure.

A bonding material (3) is provided between the back surface of the first chip (1) and the back surface of the second chip (2). This bonding material is preferably insulative. The surface of either one of the chips (1, 2) is joined to the interposer (4). The interposer (4) has a surface to be joined to the printed wiring board.

The connection electrode (2) is connected to the interposer (4).
1) is formed, the first chip (1) is disposed between the interposer (4) and the second chip (2), and the electrode pads (12) are disposed on the front side of the second chip (2). Preferably, the connection electrode (21) and the electrode pad (12) are connected by a bonding wire (13).

The interposer (4) has two layers of metal wirings (21, 7) on the front and back sides thereof, and the two layers of metal wirings (21, 7) are connected through through holes to form a first layer. It is preferable that a connection electrode (11) is arranged on the surface side of the chip (1), and the connection electrode (11) is connected to the metal wiring (21). Furthermore, it consists of a solder bump (8), and the solder bump (8) is connected to the metal wiring (21).

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Corresponding to the drawings, an embodiment according to the present invention includes a first chip and a second chip. As shown in FIG. 1, the first chip 1 and the second chip 2 are joined via a mount layer 3. The first chip 1 is bonded to the mount layer 3 face down (at the back side), and the back side of the first chip 1 is in close contact with the mount layer 3. The second chip 2
It is bonded face down to the mount layer 3 and the second
The back surface of the chip 2 is in close contact with the mount layer 3.
Here, the back surface is defined as a surface on which electrodes or circuits are not formed, and the front surface is defined as a surface on which electrodes or circuits are formed. The surface can be expressed as a circuit formation surface or an electrode formation surface.

The interposer 4 is joined to the front side (lower side) of the first chip 1. Interposer 4
Is formed from an adhesive layer 5, a base film 6, a metal wiring layer 7, an inner solder bump 8, and a solder resist 9. The base film 6 is bonded to the first chip via the adhesive layer 5 by thermocompression. A material having thermoplasticity and thermosetting properties is used for the adhesive layer 5. The first electrode pad 11 belongs to the first chip 1 and is located on the front surface side of the first chip 1. The inner solder bumps 8
It penetrates through the adhesive layer 5 and the base film 6. The electrode pads 11 and the metal wiring layers 7 are electrically connected by the inner solder bumps 8.

The second chip 2 is joined to the back surface (upper surface) of the first chip 1 by a paste-like or film-like mounting material 3 so as to face up. First
When the potentials of the substrates of the chip 1 and the second chip 2 are different, the material of the mount layer 3 needs to be insulative. Second electrode pad 12 of second chip 2
Are electrically connected to the inner solder bumps 8 by metal wires 13 such as gold by wire bonding.

The metal wire 13 is connected to the metal wiring layer 7 of the interposer 4 via the inner solder bump 8. The exposed surfaces of the second chip 2, the metal wires 13, and the interposer 4 are sealed with a sealing resin 14. Both side surfaces 15 of the first chip 1 and both side surfaces 16 of the second chip 2 form the same plane, particularly the same plane, respectively. The first chip 1 and the second chip 2 have the same size on the plane. Is preferred. A plurality of solder balls 17 are joined to the metal wiring layer 7 at a plurality of sites not covered by the solder resist 9. A stacked package including the first chip 1, the second chip 2, and the interposer 4 is mounted on a printed wiring board (not shown) via solder balls 17. The first chip 1 and the second chip 2 are joints of the back surfaces, and can be made the same size.

FIG. 2 shows another embodiment according to the present invention, and shows a chip stack type package. No inner bump is used for connection between the electrode pad 12 and the metal wiring layer 7. An opening 18 is opened at an appropriate portion of the interposer 4, and one end of the metal wire 13 is directly electrically connected to the metal wiring layer 7 without passing through the inner bump.

FIG. 3 shows still another embodiment according to the present invention, and shows a chip stack type package.
This embodiment is easy to realize when the interposer forms part of a printed circuit board. The base film 6 of the interposer 4 is formed as a printed board. The first chip 1 and the printed board 6 are flip-mounted, and an underfill 19 made of a liquid thermosetting resin is provided in a gap between the first chip 1 and the printed board 6.
Is filled. The second chip 2 is bonded to the back surface of the first chip 1 via a mount layer 3 in a paste or film shape so as to face up.

An upper electrode 21 is formed on the upper surface of the base film 6. A solder bump 8 is formed in alignment with the first electrode pad 11, and after flip-chip mounting, an underfill 19 is filled between the chip and the interposer. The first electrode pad 11 is connected to the upper electrode 21 via the solder bump 22. As described above, the first chip 1 is mounted face-down on the interposer 4 and flip-chip mounted. The upper electrode 21 and the metal wiring layer 7 are connected via a through hole formed in the base film 6.

As described above, since the two chips are joined and laminated on the back surface, all the electrode pads are located on both sides of the laminated chip. In this case, the electrode pads of the first chip 1 on the side in contact with the interposer can be electrically connected to the metal wiring layer by using inner bumps formed in the interposer 4. Also,
The electrode pads of the second chip 2 on the side not in contact with the interposer can be electrically connected to the metal wiring layer using metal wires. Therefore, there is no restriction on the combination of chip sizes due to wiring restrictions, and packaging of chips of the same size can be easily performed. In addition, wiring using metal wires is used only for connection between the second chip and the metal wiring layer, so that not only the package structure becomes extremely simple, but also the accessibility of the electrode pads is improved. Such a simple method of electrical connection with the second chip makes it possible to improve workability and integration in packaging.

[0018]

According to the laminated chip semiconductor device of the present invention, it is possible to improve the integration of chips arranged three-dimensionally and to suppress an increase in planar size.

[Brief description of the drawings]

FIG. 1 is a sectional view showing an embodiment of a laminated chip semiconductor device according to the present invention.

FIG. 2 is a sectional view showing another embodiment of the laminated chip semiconductor device according to the present invention.

FIG. 3 is a sectional view showing still another embodiment of the stacked chip semiconductor device according to the present invention.

FIG. 4 is a cross-sectional view showing a known package.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... 1st chip 2 ... 2nd chip 3 ... Bonding material 4 ... Interposer 11 ... Connection electrode 12 ... Electrode pad 17 ... Solder ball 21 ... Connection electrode

Claims (8)

[Claims] A back surface of the first chip and a back surface of the second chip are opposed to each other, and a back surface of the first chip and a back surface of the second chip are opposed to each other; A laminated chip semiconductor device on which electrodes are formed. 2. The stacked chip semiconductor device according to claim 1, wherein a bonding material is interposed between the back side of the first chip and the back side of the second chip. 3. The stacked chip semiconductor device according to claim 1, wherein a surface of one of the chips is joined to an interposer. 4. The laminated chip semiconductor device according to claim 3, wherein the interposer has a surface to be joined to a printed wiring board. 5. The interposer according to claim 3, wherein a connection electrode is formed on the interposer, the first chip is disposed between the interposer and the second chip, and an electrode pad is provided on a surface side of the second chip. Wherein the connection electrode and the electrode pad are connected by a bonding wire. 6. The interposer according to claim 3, wherein the interposer has two layers of metal wiring on the front and back sides thereof, wherein the two layers of metal wiring are connected via through holes, and A connection electrode disposed on a side of the stacked chip semiconductor device, wherein the connection electrode is connected to the metal wiring. 7. The laminated chip semiconductor device according to claim 6, further comprising a solder bump, wherein the solder bump is connected to the metal wiring. 8. The stacked chip semiconductor device according to claim 1, wherein the two chips have the same planar shape.