Active solid-state devices (e.g. – transistors – solid-state diode – Lead frame – With structure for mounting semiconductor chip to lead frame
Reexamination Certificate
2000-12-15
2004-08-03
Loke, Steven (Department: 2811)
Active solid-state devices (e.g., transistors, solid-state diode
Lead frame
With structure for mounting semiconductor chip to lead frame
C257S666000, C257S787000, C257S784000, C257S783000, C257S690000
Reexamination Certificate
active
06770959
ABSTRACT:
FIELD OF THE INVENTION
This invention relates to a structure of semiconductor package without substrate and particularly a semiconductor package which has no substrate for reducing the package thickness and enhancing production yield and method of manufacturing same.
BACKGROUND OF THE INVENTION
The commonly used semiconductor packaging process generally includes the following steps: In dicing saw process, the wafer was cut into individual chip by means of wafer dicing machines according to a preset integrated circuit (IC) street mapped on the wafer; In die bonding process, the chip was mounted on a prefabricated lead frame or substrate; In wire bonding process, the chip and the lead were connected electrically by means of bonding wires such as gold (Au) wires, copper (Cu) wires or aluminum (Al) wires, then molding the chip and bonding wires in a package by molded resin for protecting the semiconductor from damping, contamination or damage.
With increasing demands of enhancing function and speed for the electronic products, there is a constant pressure to build and pack more circuit elements in the IC. The size of the chip thus becomes bigger. However one of the contemporary design requirements for electronic products need slim size and light weight. Hence wafer producers are under great pressure to increase circuit density in IC chip including more function but without increasing the IC dimension. The chip package also has to meet this trend of slim size and light weight for saving space in the circuit board for semiconductor devices. Numerous package techniques and methods have been proposed for meeting this requirement.
FIGS. 1A and 1B
illustrate a conventional semiconductor package method named quad flat non-leaded (QFN) package. The chip
1
is adhered to a die pad
32
located on a prefabricated lead frame
3
by silver paste
2
, and the chip
1
is connected to a lead
31
through bonding wires
5
in wire bonding process. Thereafter, a molding process is performed. As the QFN package has only a half covered by molded resin
6
, said lead
31
exposed outside the bottom side of the lead frame
3
is prone to form a flash
7
after the molding process. As a result, the subsequent manufacturing processes might be adversely affected.
For preventing the flash
7
from taking place, a conventional method is to adhere a high-temperature-resistant tape
8
to the bottom side of the lead frame
3
(shown in FIG.
2
A). After the wire bonding process, the lead frame
3
stuck with the tape
8
is transported to the molding process. When the molding process is finished and the molded resin
6
is solidified, the tape
8
is removed (shown in FIG.
2
B). This method needs additional steps of adhering the tape
8
to the lead frame
3
and removing the tape
8
later. This additional process makes production cost higher. Furthermore, as the tape
8
is a pliable material without hard and rigid property, it has a buffer effect on the lead frame
3
during wire bonding process, such as in thermo sonic (T/S) process or thermo compress (T/C) process, and may result in not even transmission of bonding force. Consequently, the bonding force might be negatively impacted and result in dropping of bondability.
FIG. 3
depicts another common problem happened to conventional wire bonding process. During the process, the lead frame
3
is placed on a heat block
9
and is held thereon by a window clamp
10
at the upper side for holding the lead
31
securely. Then the upper side of the chip
1
and the lead
31
are electrically connected by bonding wires
5
at two ends thereof. As the lead
31
of the QFN package product generally has a smaller surface and finer pitch, it is more difficult to securely hold the lead
31
between the heat block
9
and window clamp
10
during wire bonding process. The lead
31
tends to vibrate during the wire bonding process and may result in poorer bondability.
Moreover, every product needs a unique lead frame
3
for supporting and wiring the chip
1
. It takes more time and cost in design and production. The lead frame
3
also takes considerable size and height in a finished package. This becomes another concern in designing slim and light products.
U.S. Pat. No. 5,869,905 discloses a semiconductor package structure which omits the lead frame for saving the package height. It includes a substrate which has a surface larger than the chip. The substrate has a through-hole for holding the back side of the chip on the substrate by vacuum suction force through the through-hole. In wire bonding process, the upper side of the chip and the substrate are connected by bonding wires. After the molding process in which the chip and bonding wires are encapsulated by a molding compound, the perforated substrate is removed for getting a package which has the bonding wires exposed directly to the surface of the molding compound.
Because of no substrate, the U.S. Pat. No. 5,869,905 package has a smaller size. However it still has the following disadvantages:
1. Holding the chip by vacuum suction force needs high precision equipment. A slight surface defect or not smoothness on the chip could cause chip displacement and may affect subsequent wire bonding process.
2. During wire bonding process, the bonding wires are directly soldered to the surface of the substrate, but the chip and substrate are not permanently engaged with each other (i.e. a temporarily engagement by vacuum force). The chip and substrate are easy to produce relative displacement when subject to an external force. This may cause break down of the bonding wire joints and form a flash in molding process.
3. The package loses a significant heat dissipating channel because of the omission of the lead frame.
4. The bonding wires are exposed to the surface of the molded resin after the package is completed. The exposed bonding wire is too small and is difficult for soldering on a circuit board in subsequent processes. To increase the soldering size will need additional process after the package is finished which will result in higher cost.
SUMMARY OF THE INVENTION
In view of the foregoing disadvantages, it is therefore an object of this invention to provide a structure and production method for semiconductor package which has no substrate so that flash may be prevented from happening to the exposed lead.
It is another object of this invention to eliminate the adhesive tape for improving the flash phenomenon and to provide a higher rigid substrate for wire bonding process, so that the bonding force may be fully transmitted to increase bondability.
It is a further object of this invention to provide a thin lead layer to replace conventional lead frame for engaging with a substrate to reduce total package thickness, and to hold the chip without the conventional clamping means so that the chip and lead won't vibrate during wire bonding process, and the package may has a heat dissipating channel to facilitate subsequent manufacturing processes.
It is yet another object of this invention to provide a simple structure and method for improving the packaging process, and enhancing product quality and production yield.
In order to achieve aforesaid objects, this invention provides an interim substrate covered by a solder mask at selected areas. The surface of the interim substrate that are not covered by the solder mask have a plurality of lead layers and die pad layers formed thereon at selected locations. The interim substrate provides a firm support base for bonding wires soldering on the lead layers during wire bonding process. After molding process is completed, and singulation processes are finished, the interim substrate is removed by etching process.
REFERENCES:
patent: 5866948 (1999-02-01), Murakami et al.
patent: 5869905 (1999-02-01), Takebe
patent: 5976912 (1999-11-01), Fukutomi et al.
patent: 6001671 (1999-12-01), Fjelstad
patent: 6111306 (2000-08-01), Kawahara et al.
patent: 6191494 (2001-02-01), Ooyama et al.
patent: 6455926 (2002-09-01), Ho
patent: 4-148553 (1992-05-01), None
Huang Chien-Ping
Jao Raymond J. M.
Bacon & Thomas
Loke Steven
Parekh Nitin
Silconware Precision Industries Co., Ltd.
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