Active solid-state devices (e.g. – transistors – solid-state diode – Combined with electrical contact or lead – Flip chip
Reexamination Certificate
2000-06-22
2001-12-18
Clark, Jhihan B (Department: 2815)
Active solid-state devices (e.g., transistors, solid-state diode
Combined with electrical contact or lead
Flip chip
C257S690000, C257S776000, C257S750000, C257S758000
Reexamination Certificate
active
06331736
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to trace formation in the fabrication of semiconductor devices. More particularly, the present invention relates to the formation of routing traces on an external surface of a semiconductor device.
2. State of the Art
Integrated circuit (“IC”) devices generally consist of a plurality of components (such as resistors, capacitors, diodes, transistors, fuses, conductors, and the like) fabricated on a single semiconductor chip. Each of these components is electrically isolated from one another by dielectric materials. Thus, in order to interact with one another to form an integrated circuit, a plurality of conductive interconnections (hereinafter “traces”) must be formed between the components.
FIG. 10
illustrates an exemplary trace configuration connecting a pair of pinch resistors
202
A and
202
B in series in an IC device. First and second pinch resistors
202
A and
202
B, respectively, are formed in a p-type substrate
206
by doping n-type regions
208
A and
208
B, respectively, into the p-type substrate
206
. P-type regions
214
A and
214
B, respectively, are doped into the n-type regions
208
A and
208
B to reduce the cross-sectional area of the resistor, thereby increasing its respective resistance. A first trace
218
A is disposed atop a dielectric layer
222
and routes an electric current to the first pinch resistor
202
A through a first contact
224
A through the dielectric layer
222
. The electric current travels through the first pinch resistor
202
A and through a second contact
224
B through the dielectric layer
222
. A second trace
218
B is disposed atop the dielectric layer
222
and is in electrical contact with the second contact
224
B. The second trace
218
B routes the electric current to the second pinch resistor
202
B by a third contact
224
C through the dielectric layer
222
. The electric current travels through the second pinch resistor
202
B and exits through a fourth contact
224
D through the dielectric layer
222
. A third trace
218
C is disposed atop the dielectric layer
222
and is in electrical contact with the fourth contact
224
D to route the electric current to other components in the IC device.
Higher performance, lower cost, increased miniaturization of the components comprising the IC devices, and greater packaging density of IC devices are ongoing goals of the computer industry. The advantages of increased miniaturization of components include: reduced-bulk electronic equipment, improved reliability by reducing the number of solder or plug connections, lower assembly and packaging costs, and improved circuit performance. In pursuit of increased miniaturization, IC devices have been continually redesigned to achieved ever-higher degrees of integration which has reduced the size of the IC device. However, as the dimensions of the IC devices are reduced, the geometry of the components and circuit elements has also decreased. Moreover, as components become smaller and smaller, tolerances for all semiconductor structures (such as circuitry traces, contacts, dielectric thickness, and the like) become more and more stringent. Although the reduction in size creates technical problems, the future advancement of the technology requires such size reductions.
Of course, the reduction in component size and density packing (smaller component-to-component spacing) of the components in the IC devices has resulted in a greatly reduced area for running traces to interconnect the components. Furthermore, the integration and densification process in IC devices has caused the continuous migration of traces and connections, which were previously routed on printed circuit boards, cards, and modules, to the IC device itself, yet further reducing potential area for forming traces. Thus, multilevel metallization has become a technique to cope with the reduced area. Multilevel metallizaton is a technique of forming traces on different layers of dielectric material over the components.
FIG. 11
illustrates an exemplary four-tier metallization structure
240
. The metallization structure
240
shows an active area
242
formed in a semiconductor substrate
244
which is in electrical communication with a first level trace
246
A, such as aluminum, tungsten, titanium, or various alloys thereof. The first level trace
246
A is disposed over a first level barrier layer
248
A, such as a silicon nitride layer, which is over the semiconductor substrate
244
. A first level dielectric layer
252
A is disposed over the first level trace
246
A and the exposed first level barrier layer
248
A. A second level barrier layer
248
B is disposed over the first level dielectric layer
252
A and a second level trace
246
B is formed on the second level barrier layer
248
B. The first level trace
246
A and the second level trace
246
B are in electrical communication through a first-to-second level contact
258
A which extends through the first level dielectric layer
252
A and the second level barrier layer
248
B.
A second level dielectric layer
252
B is disposed over the second level trace
246
B and the exposed second level barrier layer
248
B. A third level barrier layer
248
C is diposed over the second level dielectric layer
252
B and a third level trace
246
C is formed on the third level barrier layer
248
C. The second level trace
246
B and the third level trace
246
C are in electrical communication through a second-to-third level contact
258
B which extends through the second level dielectric layer
252
B and the third level barrier layer
248
C.
A third level dielectric layer
252
C is disposed over the third level trace
246
C and the exposed third level barrier layer
248
C. A fourth level barrier layer
248
D is disposed over the third level dielectric layer
252
C and a fourth level trace
246
D is formed on the fourth level barrier layer
248
D. The third level trace
246
C and the fourth level trace
246
D are in electrical communication through a third-to-fourth level contact
258
C which extends through the third level dielectric layer
252
C and the fourth level barrier layer
248
D.
A fourth level dielectric layer
252
D is disposed over the fourth level trace
246
D and the exposed fourth level barrier layer
248
D. The upper surface
284
of the fourth level dielectric layer
252
D is used to form bond pads
286
in specific locations and external communication traces
288
conduct input/output signals to solder balls
292
. The solder balls
292
will be connected to external devices, such as a printed circuit board, to relay input/output signals therebetween.
FIG. 12
is a top view of the metallization structure
240
of
FIG. 11
prior to the addition of solder balls
292
. As
FIG. 12
illustrates, the bond pads
286
are patterned in specific locations for active surface-down mounting to contact sites of metal conductors of a carrier substrate (not shown), such as a printed circuit board, FR
4
, or the like, wherein the contact sites are a mirror-image of the bond pads
286
pattern on the metallization structure
240
. It is, of course, understood that although the bond pads
286
are illustrated as substantially square, they can be of any shape, including round, as shown as round bond pad
294
.
Although multilayer metallization is effective in compensating for reduced areas for trace patterning, the thickness of the IC device is also a concern. Therefore, it can be appreciated that it would be advantageous to develop a technique which would maximize the available area on an IC device for patterning traces for the interconnection of IC device components, without adding additional layers to the multilayer structure.
BRIEF SUMMARY OF THE INVENTION
The present invention relates to the formation of routing traces on an external surface of a semiconductor device. In an exemplary method of the present invention, a flip-chip is provided which has an active surface bearing a plurality of bonds pads upon which minute solder balls or other conductive mat
Duesman Kevin G.
Farnworth Warren M.
Clark Jhihan B
Micro)n Technology, Inc.
TraskBritt
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