Semiconductor device manufacturing: process – Packaging or treatment of packaged semiconductor – Metallic housing or support
Reexamination Certificate
2001-05-11
2003-08-26
Lebentritt, Michael S. (Department: 2824)
Semiconductor device manufacturing: process
Packaging or treatment of packaged semiconductor
Metallic housing or support
C438S120000, C438S119000, C257S720000, C257S723000
Reexamination Certificate
active
06610560
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to semiconductor packaging technology, and more particularly, to a chip-on-chip (COC) based multi-chip module (MCM) with molded underfill and method of fabricating the same.
2. Description of Related Art
Multi-chip module (MCM) is a type of semiconductor package that is used to pack two or more semiconductor chips in one single package unit, so that one single package unit is capable of offering a manifold level of functionality or data storage capacity. Memory chips, such as flash memory chips, are typically packaged in this way so as to allow one single memory module to offer an increased data storage capacity.
A conventional method for fabricating a small-size multi-chip module is through the use of chip-on-chip (COC) technology, by which one semiconductor chip is arranged in an upside-down flip chip manner over the active surface of another chip and bonded to the same by means of an array of solder bumps. The COC technology has the benefit of allowing the finished package unit to have a reduced height.
One problem to the COC architecture, however, is that a flip-chip undergap would be undesirably left between the overlying chip and the underlying chip due to the existence of solder bumps therebetween. This flip-chip undergap, if not underfilled, would easily cause the two chips to suffer from fatigue cracking and electrical failure when the entire package structure is being subjected to high-temperature conditions. As a solution to this problem, it is an essential step in the fabrication of a COC-based multi-chip module to fill an underfill material, such as resin, into such the flip-chip undergap, so as to provide mechanical reinforcement to the two chips. The involved process step is customarily referred to as flip-chip underfill.
A conventional method for fabricating a COC-based multi-chip module is illustratively depicted in the following with reference to
FIGS. 1A-1D
.
Referring first to
FIG. 1A
, by this conventional method, the first step is to prepare a circuited substrate
100
and at least three semiconductor chips, including a first semiconductor chip
110
, a second semiconductor chip
120
, and a third semiconductor chip
130
.
The circuited substrate
100
is a conventional and well-known substrate type for BGA application, which has a front surface
100
a
and a back surface
100
b
, and whose front surface
100
a
is used for mounting the chips
110
,
120
,
130
, while the back surface
100
b
is used for the implantation of a ball grid array (shown later in
FIG. 1D
with the reference numeral
180
).
The first semiconductor chip
110
has an active surface
110
a
and an inactive surface
110
b
, and whose inactive surface
110
b
is adhered to the front surface
100
a
of the circuited substrate
100
and whose active surface
110
a
is electrically coupled to the circuited substrate
100
by means of a plurality of bonding wires
111
, such as gold wires.
The second semiconductor chip
120
has an active surface
120
a
and an inactive surface
120
b
, and whose active surface
120
a
is mechanically bonded and electrically coupled to the active surface
110
a
of the first semiconductor chip
110
through COC technology by means of an array of solder bumps
121
. As the second semiconductor chip
120
is mounted in position over the first semiconductor chip
110
, however, a flip-chip undergap
122
would be undesirably left therebetween due to the existence of the solder bumps
121
.
The third semiconductor chip
130
has an active surface
130
a
and an inactive surface
130
b
, and whose active surface
130
a
is also mechanically bonded and electrically coupled to the active surface
110
a
of the first semiconductor chip
110
through COC technology by means of an array of solder bumps
131
. As the third semiconductor chip
130
is mounted in position over the first semiconductor chip
110
, however, a flip-chip undergap
132
would be undesirably left therebetween due to the existence of the solder bumps
131
.
Referring further to
FIG. 1B
, in the next step, a flip-chip underfill process is performed to form a flip-chip underfill layer
140
to fill up the entirety of the flip-chip undergaps
122
,
132
.
Referring further to
FIG. 1C
, in the next step, a molding process is performed by fixing the semi-finished package assembly of
FIG. 1B
in a molding tool
150
having a mold injection inlet
151
. As the semi-finished package assembly of
FIG. 1B
is fixed in position in the molding tool
150
, a molding material
160
, such as epoxy resin, is injected through the mold injection inlet
151
into the molding tool
150
until the molding material
160
substantially fills up all the void spaces in the molding tool
150
.
Referring further to
FIG. 1D
, through the forgoing molding process, an encapsulation body
170
is formed to encapsulate all the semiconductor chips
110
,
120
,
130
over the circuited substrate
100
. After this, a ball-implantation process is performed to implant an array of solder balls (i.e., ball grid array)
180
over the back surface
100
b
of the circuited substrate
100
. This completes the fabrication of the multi-chip module by the conventional method.
One drawback to the forgoing conventional method, however, is that, since the flip-chip underfill layer
140
is different in coefficient of thermal expansion (CTE) from the encapsulation body
170
, it would easily cause the breaking of the bonding wires
111
during subsequent TCT (Temperature Cycle Test) or TST (Thermal Shock Test) testing procedures.
Some related patents are listed in the following:
U.S. Pat. No. 6,038,136 “CHIP PACAKGE WITH MOLDED UNDERFILL”;
U.S. Pat. No. 5,923,090 “MICROELECTRONIC PACAKGE AND FABRIATION THEREOF”;
U.S. Pat. No. 5,892,289 “BARE CHIP MOUNTING STRUCTURE AND MANUFACTURING METHOD THEREFOR”;
U.S. Pat. No. 5,646,828 “THIN PACKAGING OF MULTI-CHIP MODULES WITH ENHANCED THERMAL POWER MANAGEMENT”;
U.S. Pat. No. 5,608,262 “PACKAGING MULTI-CHIP MODULES WITHOUT WIRE-BOND INTERCONNECTION”.
The U.S. Pat. No. 6,038,136 teaches the provision of a vent hole in the substrate to help the molding material to fill freely into the flip-chip undergaps to form a molded underfill layer. One drawback to this patent, however, is that the drilling of a vent hole in the substrate of each package unit would make the overall packaging process more complex in procedural steps. The U.S. Pat. No. 5,923,090, No. 5,892,289, No. 5,646,828, and No. 5,608,262 disclose various types of COC technologies. However, none of them teach a cost-effective solution to the problem of molded underfill.
SUMMARY OF THE INVENTION
It is therefore an objective of this invention to provide a new semiconductor packaging technology for fabrication of COC-based multi-chip module with molded underfill, which can help prevent the bonding wires from breaking during TCT or TST testing procedures.
In accordance with the foregoing and other objectives, the invention proposes a new semiconductor packaging technology for fabrication of COC-based multi-chip module.
The new semiconductor packaging technology according to the invention is characterized by the provision of a side gap of an empirically-predetermined width between the overlying chips mounted through COC technology over an underlying chip to serve as an air vent which allows the injected molding material to fill freely into the flip-chip undergaps during molding process.
Fundamentally, the underfill effect is related to a number of factors, including the flowability of the molding material, the size of the overlying chips, and the quantity of the solder bumps. Therefore, in actual application, the exact width of the side gap should be determined empirically through experiments.
Based on experimental data, it is found that the width of the side gap should be equal to or less than 0.3 mm (millimeter). The optimal value for the side gap width may be varied for different package specifications. For instance, in the case of the overlying chips being 3.5
Lin Caesar
Pu Han-Ping
Wang Yu-Po
Corless Peter F.
Jensen Steven M.
Lebentritt Michael S.
Siliconware Precision Industries Co. Ltd.
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