Semiconductor device manufacturing: process – Packaging or treatment of packaged semiconductor – Metallic housing or support
Reexamination Certificate
2001-11-30
2004-09-14
Ghyka, Alexander (Department: 2812)
Semiconductor device manufacturing: process
Packaging or treatment of packaged semiconductor
Metallic housing or support
C438S462000, C257S620000, C257S701000, C257S718000
Reexamination Certificate
active
06790709
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to the backside metallization and dicing of microelectronic device wafers. In particular, the present invention relates to forming a substantially V-shaped notch extending into the microelectronic device wafer from a back surface thereof prior to metallization and dicing.
2. State of the Art
In the production of microelectronic devices, integrated circuitry is formed in and on semiconductor wafers, which is usually comprised primarily of silicon, although other materials such as gallium arsenide and indium phosphide may be used. As shown in
FIG. 8
, a single microelectronic device wafer
200
may contain a plurality of substantially identical integrated circuit areas
202
, which are usually substantially rectangular and arranged in rows and columns. Two sets of mutually parallel sets of lines or “scribe streets”
204
extend perpendicular to each other over substantially the entire surface of the microelectronic device wafer
200
between each discrete integrated circuit area
202
.
After the integrated circuit areas
202
have been subjected to preliminary testing for functionality (wafer sort), the microelectronic device wafer
200
is diced (cut apart), so that each area of functioning integrated circuitry
202
becomes a microelectronic die that can be used to form a packaged microelectronic device. One exemplary microelectronic wafer dicing process uses a circular diamond-impregnated dicing saw, which travels down the scribe streets
204
lying between each of the rows and columns. Of course, the scribe streets
204
are sized to allow passage of a wafer saw blade between adjacent integrated circuit areas
202
without causing damage to the circuitry therein.
As shown in
FIGS. 9 and 10
, a microelectronic device wafer
200
may have guard rings
206
which substantially surround the integrated circuit areas
202
. The guard rings
206
extend though an interconnection layer
208
(see FIG.
10
). The interconnection layer
208
comprises layers
212
of metal traces separated by layers of dielectric material layers on a semiconductor wafer
214
. The interconnection layer
208
provides routes for electrical communication between integrated circuit components within the integrated circuits. The guard ring
206
is generally formed layer by layer as each layer
212
is formed. The guard ring
206
assists in preventing external contamination encroaching into the integrated circuitry
202
between the layers
212
. The microelectronic device wafer
200
also includes a backside metallization layer
216
on a back surface
218
of the semiconductor wafer
214
, which will be subsequently discussed.
Prior to dicing, the microelectronic device wafer
200
is mounted onto a sticky, flexible tape
222
(shown in
FIG. 10
) that is attached to a ridge frame (not shown). The tape
222
continues to hold the microelectronic die after the dicing operation and during transport to the next assembly step. As shown in
FIGS. 11 and 12
, a saw cuts a channel
220
in the scribe street
204
through the interconnection layer
208
, the semiconductor wafer
214
, and the backside metallization layer
216
. During dicing, the saw generally cuts into the tape
222
to up to about one-third of its thickness. The dicing of the wafer forms individual microelectronic dice
224
.
As shown in
FIG. 13
, a microelectronic die
224
is attached to a substrate
226
, such as a motherboard, by a plurality of solder balls
228
extending between interconnection layer
208
and the substrate
226
. A heat dissipation device
232
is attached to the backside metallization layer
216
by a thermal interface material
234
. The thermal interface material
234
is usually a solder material including, but not limited to, lead, tin, indium, silver, copper, and alloys thereof. However, it is well known that most solders do not wet (i.e., stick to) semiconductor wafers
214
(particularly silicon-based semiconductor wafers). Thus, the backside metallization layer
216
is selected to adhere to the semiconductor wafer back surface
218
and wet with the thermal interface material
234
. The backside metallization layer
216
is usually a metal material including, but not limited to, gold, silver, nickel, and the like.
However, in the dicing of microelectronic device wafers
200
, dicing saws (metal impregnated with diamond) may cause chipping of the backside metallization layer
216
to expose a portion of the semiconductor wafer back surface
218
. Since the thermal interface material
234
does not wet the semiconductor wafer back surface
218
, microgaps
236
form between the thermal interface material
234
and the semiconductor wafer back surface
218
, and a poor (sagging) thermal interface material fillet
238
results between the heat dissipation device
232
and the backside metallization layer
216
, as shown in FIG.
14
.
During the operation of the microelectronic die
224
stresses occur at the interface between the backside metallization layer
216
and the thermal interface material
234
, particularly at comers/edges
244
of the microelectronic die
224
. These stresses can result in delamination, generally starting at the microelectronic die comers/edges
242
. This delamination results in a decrease in thermal conductivity and moisture encroachment. With a decrease in thermal conductivity comes the risk of overheating in the microelectronic die
224
, which can result in the damage or destruction thereof. The microgaps
236
and the poor thermal interface material fillet
238
exacerbate the delamination.
Therefore, it would be advantageous to develop techniques to effectively dice microelectronic device wafers while reducing or substantially eliminating the possibility of delamination propagation.
REFERENCES:
patent: 5693981 (1997-12-01), Schneider et al.
patent: 5936304 (1999-08-01), Lii et al.
patent: 6049124 (2000-04-01), Raiser et al.
patent: 6455920 (2002-09-01), Fukasawa et al.
Chandran Biju
Dias Rajen
Ghyka Alexander
Intel Corporation
Winkle Rob G.
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