Active solid-state devices (e.g. – transistors – solid-state diode – Housing or package – Outside periphery of package having specified shape or...
Reexamination Certificate
2003-07-15
2004-08-31
Clark, Jasmine (Department: 2815)
Active solid-state devices (e.g., transistors, solid-state diode
Housing or package
Outside periphery of package having specified shape or...
C257S678000, C257S776000, C257S688000, C257S780000
Reexamination Certificate
active
06784542
ABSTRACT:
BACKGROUND OF THE INVENTION
The present invention generally relates to semiconductor devices and more particularly to a semiconductor device having a ball grid array and a fabrication process thereof, including a transportation tray used in the fabrication process of the semiconductor device. Further, the present invention relates to the fabrication process of a semiconductor substrate used for such a semiconductor device.
With ever-increasing demand of size reduction of electronic apparatuses, efforts are being made for decreasing the size and increasing the integration density of semiconductor devices. In relation to this, there is a proposal of a so-called chip-size package structure in which the overall size of the semiconductor device is made close to the size of the semiconductor chip therein.
In order to achieve such a real chip-size package structure, as well as for improving the efficiency of production of the semiconductor devices having such a package structure, there is a proposal of a wafer-level packaging process in which a substrate carrying a plurality of semiconductor devices thereon is subjected to a packaging process in the state that the semiconductor devices are still on the semiconductor substrate, followed by a dicing process to form individual semiconductor chips corresponding to the semiconductor devices.
FIG. 1
shows an example of a semiconductor device
10
A fabricated according to a conventional wafer-level packaging process.
Referring to
FIG. 1
, the semiconductor device
10
A generally includes a semiconductor chip
1
A, a resin package layer
2
and a plurality of bump electrodes
3
.
More specifically, the semiconductor device
10
A carries the resin package layer
2
on the surface of the semiconductor chip
1
A on which active devices (monolithic electronic circuits) and the bump electrodes
3
are formed. The substrate is then diced into individual semiconductor devices
10
A. The semiconductor device
10
A thus formed has a size substantially identical to the size of the semiconductor chip
1
A.
FIG. 2
shows the construction of a conventional transportation tray
5
used for transporting the semiconductor device
10
A of FIG.
1
.
Referring to
FIG. 2
, the transportation tray
5
includes a tray main-body
6
accommodating therein the semiconductor device
10
A, and a cap
7
is provided on the train main-body
6
so as to cover the opening of the tray main-body
6
. The tray main-body
6
includes a bottom overhang part
8
wherein the bottom overhang part
8
supports the semiconductor device
10
A by engaging the resin package layer
2
on the semiconductor chip
1
A. The overhang part
8
defines an opening for accommodating the bump electrodes
3
in the state that the semiconductor device
10
A is held inside the transportation tray
5
.
FIG. 3
shows another conventional semiconductor device
10
B fabricated according to a conventional wafer-level packaging process.
Referring to
FIG. 3
, the semiconductor device
10
B generally includes, in addition to the semiconductor chip
1
A described in
FIG. 1
, bump electrodes
4
formed on the semiconductor chip
1
A and a circuit substrate
9
provided on the bump electrodes
4
in electrical as well as mechanical connection with the bump electrodes
4
, wherein an under-fill resin layer
11
is formed so as to fill the gap between the semiconductor chip
1
A and the circuit substrate
9
. It should be noted that the bump electrodes
3
forming a ball grid array are formed on the bottom surface of the circuit substrate
9
. By using the circuit substrate
9
, which carries wiring patterns thereon, a dense array of the bump electrodes
3
becomes possible.
FIG. 4
shows a further conventional semiconductor device
10
C fabricated according to a conventional wafer-level packaging process.
Referring to
FIG. 4
, the semiconductor device
10
C has a construction generally identical with the construction of the semiconductor device
10
B except that a thin semiconductor chip
1
B is used. The semiconductor chip
1
B having such a reduced thickness may be formed by grinding the rear surface of the semiconductor chip
1
A.
FIGS. 5A-5D
are diagrams showing an example of the fabrication process of a conventional semiconductor device.
In recent process of fabricating semiconductor devices, there is a tendency to increase the size of the semiconductor substrate so as to maximize the efficiency of production of the semiconductor devices. In order to obtain such a large-diameter semiconductor substrate, it is necessary to slice a large-diameter semiconductor crystal ingot by a wire saw machine and process the both surfaces of the large-diameter semiconductor wafer thus obtained.
FIG. 5A
shows a semiconductor substrate
12
A immediately after the sawing process. As can be seen in
FIG. 5A
, the both surfaces of the semiconductor substrate
12
A form a rough surface, and thus, a smoothing process is essential in order that the semiconductor substrate
12
A can be used for the substrate of a semiconductor device.
Thus, in the step of
FIG. 5B
, a hypothetical target surface state
13
is set for the semiconductor substrate
12
A, and the rear surface (top surface in the example of
FIG. 5B
) of the semiconductor substrate
12
A is processed in the step of
FIG. 5C
while using the top surface as a reference surface, such that the state of the rear surface reaches the target surface state
13
. Further, the front surface (bottom surface in the example of
FIG. 5B
) is processed similarly in the step of FIG.
5
D. The semiconductor devices
10
A,
10
B or
10
C are formed on such a semiconductor substrate
12
A in a row and column formation.
As noted already, the semiconductor device
10
A has an advantageous feature in that the desired high-density mounting is possible on a circuit substrate of an electronic apparatus. On the other hand, it should be noted that the semiconductor device
10
A has a composite structure
10
in which the semiconductor chip
1
A carries a resin layer
2
on the side where the electrode bumps
3
are formed. As the resin layer
2
has a property substantially different from the property of the semiconductor chip
1
A or the semiconductor substrate
12
C, and in view of the fact that the semiconductor chip
1
A, including the resin layer
2
thereon, has a rectangular shape defined by sharply defined edges and corners, there arises a problem, when sawing the semiconductor substrate
12
C into the semiconductor chips
1
A or when handling the semiconductor device, in that a crack may be formed at the boundary between the semiconductor substrate
12
C and the resin layer
2
. Alternatively, the semiconductor chip
1
A or the resin layer
2
itself may be cracked. The same problem occurs not only in the semiconductor chip
1
A but also in the semiconductor chip
1
B or
1
C.
Further, even in such a case in which the problem of cracking is avoided, the semiconductor device
10
A,
10
B or
10
C is still vulnerable to damages particularly at the boundary between the semiconductor chip
1
A and the resin layer
2
, and a careful handling is needed in a suitable protective environment.
Further, the use of the transportation tray
5
of
FIG. 2
in combination with the semiconductor device
10
A,
10
B or
10
C may cause the problem of rattling of the semiconductor device
10
A inside the tray main-body
6
, while such a rattling is not only disadvantageous in view of poor reliability of transportation but also in view of unreliable contact with a test bed used when testing the semiconductor device
10
A in the state that the semiconductor device
10
A is held by the transportation tray
5
. Further, the rattling of the semiconductor device
10
A in the transportation tray
5
may cause a damage in the solder bumps
3
as a result of collision with the bottom overhang part
8
of the transportation tray
5
.
In the case of the semiconductor device
10
C in which the thickness of the semiconductor chip
1
B is reduced, the semiconductor device is extremely fragile and handling of t
Fukasawa Norio
Hamanaka Yuzo
Matsuki Hirohisa
Morioka Muneharu
Nagashige Kenichi
Clark Jasmine
Fujitsu Limited
Westerman Hattori Daniels & Adrian LLP
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