Semiconductor device manufacturing: process – Coating with electrically or thermally conductive material – To form ohmic contact to semiconductive material
Reexamination Certificate
2000-10-06
2002-12-10
Elms, Richard (Department: 2824)
Semiconductor device manufacturing: process
Coating with electrically or thermally conductive material
To form ohmic contact to semiconductive material
Reexamination Certificate
active
06492263
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates generally to the manufacture of semiconductor device, and more particularly, to a dual damascene process and structure for interconnect within an integrated circuit (IC) in a semiconductor device.
BACKGROUND OF THE INVENTION
Multilayer conductor such as metal is generally formed within an IC during the manufacture of a semiconductor device. When the design rule of the semiconductor device is scaled down to under 1 &mgr;m(micron), the multilayer conductor must be applied adaptively to the high density of the semiconductor device. Similarly, the size of the wiring structure also has to be shrunk adaptively to the smaller device size. More advanced wiring structure and new material are therefore required when IC technology is developed to the range of 0.25&mgr;m. A dual damascene is thus used for such structure. The dual damascene process provides advantages of process simplification by decreasing steps of forming via holes and trenches, in which openings of metal layer wiring and via holes to connect with the underlying metal layers are produced at the same time, the procedure is advantageous to the lithography process and improves critical dimension (CD) control. Then metal is filled in the via holes and trenches by the same metal filling process, so that process steps are decreased.
Due to the simplification of steps implemented in the dual damascene process, the current use of aluminum (Al)/silicon dioxide (Si
O2
) system can be readily replaced with new materials for the dual damascene process. One of the new materials is copper (Cu). The use of Cu metalization can enhance signal transmission performance and reliability by aluminum. However, some problems hard to overcome are present when copper is applied for the Al prior art. For instance, a barrier layer is not needed between an Al metal wire and a SiO
2
inter-metal dielectric (IMD) in a conventional Al interconnect structure, however, copper must be isolated from surrounding IMD when it is used, since copper is easy to diffuse/drift to adjacent dielectrics.
FIG. 1
shows a prior art process flow for a Cu self-aligned dual damascene. As shown in
FIG. 1
a
, a barrier layer
12
, a low dielectric constant layer
14
, and an etch-stop layer
16
are formed in stack onto a copper region
10
. A portion of the etch-stop layer
16
is removed with a photoresist
18
to serve as a mask to form an opening
20
to be that shown in
FIG. 1
b
. In
FIG. 1
c
, a second low dielectric constant layer
22
overlays on the intermediate etch-stop layer
16
and fills in the opening
20
, and is overlaid with a bottom anti-reflection coating (BARC)
24
. Then a photoresist
26
is patterned and used as a mask as shown in
FIG. 1
d
, and an etching process is applied based on the pattern of the photoresist
26
, in order to remove a portion of the BARC
24
, the underlying second low dielectric constant layer
22
not covered with the photoresist
26
, and the portion of the first low dielectric constant layer
14
through the opening
20
to the top surface of the barrier layer
12
to form a trench
28
and a via hole
29
, as shown in
FIG. 1
e
. After the photoresist
26
is removed, the exposed portion of the barrier layer
12
underneath the via hole
29
is removed to expose the copper region
10
, as shown in
FIG. 1
f
. The subsequent process is to fill in the trench
28
and the via hole
29
with a conductor (not shown in the figure) to connect to the underlying copper region
10
.
Some problems exist in the above-described process. Although the dual damascene shown in
FIG. 1
is a clean process since there is no photoresist in the via hole
29
and there is no concern of the crown-like fence over the via, high etching selectivity to the intermediate barrier
14
in open area and via bottom and high overlay accuracy on photoresist patterning for dual damascene etching are very concerned. It therefore requires a thicker etch-stop layer
16
and accurate trench-to-via photo alignment control. In actual process, a thick etch-stop layer
16
will increase the equivalent dielectric constant so as to be unable to meet the low dielectric constant requirement, resulting in the increase of RC delay and disadvantages to circuit performance. On the contrary, a thin etch-stop layer
16
will make optical path difference insufficient, resulting in a weak alignment signal for wafer alignment in the subsequent process, probably causing misjudgment on the alignment step and thereby misalignment of the trench
28
to the via hole
29
, and thus increasing-resistance of the dual damascene structure. Based on same design rule, even though increasing etch selectivity of dielectric to etch-stop layer, the photo alignment signal is still weak. Furthermore, another disadvantage is contamination caused by the subsequent etching process. In
FIG. 1
f
, exposed underlying copper region
10
will sputter up onto the sidewall of the via hole
29
to cause intra-layer metal line short when the exposed portion of the barrier layer
12
underneath the via hole
29
is etched.
It is therefore desired to provide a dual damascene process and structure to improve the trench-to-via alignment and out-diffusion of metal particles, such as copper.
SUMMARY OF THE INVENTION
An object of the present invention is to provide a dual damascene process and structure for out-diffusion prevention of metal particle such as copper, in which a liner deposition is applied before the barrier layer between the via and the underlying conductive region is etched. The liner on the sidewall of the via hole could be a barrier to sputtered species for the dielectric while particles are sputtered up from the conductive region onto the sidewall of the via hole during the removal step for the barrier layer on the conductive region.
Another object of the present invention is to provide a dual damascene process and structure including a liner deposition of a material with a different refractive index from that of the intermediate etch-stop layer covered by the liner in order to more clearly distinguish the interface of oxide-liner-oxide on the sidewall of the via and then to increase trench-to-via alignment accuracy.
A further object of the present invention is to provide a dual damascene process and structure to enhance signal for both broad band and laser alignment system by pull-back of the intermediate etch-stop layer between the stacked low dielectric constant layers to produce optical path difference for the subsequent photo alignment.
In one aspect of the present invention, a dual damascene process for a semiconductor device with a barrier layer, a first low dielectric constant layer, and a first etch-stop layer in stack thereof comprises depositing a liner after forming a via hole extending through the first etch-stop layer and the first low dielectric constant layer to a surface of the barrier layer, forming a second low dielectric constant layer, a second etch-stop layer or BARC, and a trench extending through the second etch-stop layer and the second low dielectric constant layer and connecting with the via hole, removing a portion of the barrier layer underneath the via hole, and filling in the trench and the via hole with a conductor after depositing a passivation layer such as Ta/TaN for a Cu region.
In another aspect of the present invention, a dual damascene process for a semiconductor device with a barrier layer, a first low dielectric constant layer, a first etch-stop layer, a second low dielectric constant layer, and a second etch-stop layer in stack thereof comprises depositing a liner after forming a via hole extending through the first etch-stop layer and the first low dielectric constant layer to a surface of the barrier layer and a trench extending through the second etch-stop layer and the second low dielectric constant layer and connecting with the via hole, removing a portion of the barrier layer underneath the via hole, and filling in the trench and the via hole with a conductor after depositing a passivation l
Chen Chun-Wei
Lin Fu-Cheng
Peng Hsin-Tang
Elms Richard
Mosel Vitelic Inc.
Owens Beth E.
Thomas Kayden Horstemeyer & Risley
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