Radiation imagery chemistry: process – composition – or product th – Imaging affecting physical property of radiation sensitive... – Making electrical device
Reexamination Certificate
2001-02-12
2004-05-11
Duda, Kathleen (Department: 1756)
Radiation imagery chemistry: process, composition, or product th
Imaging affecting physical property of radiation sensitive...
Making electrical device
C430S317000, C438S424000, C438S700000, C438S778000, C216S017000
Reexamination Certificate
active
06733955
ABSTRACT:
BACKGROUND OF THE INVENTION
The present invention relates to the fabrication of integrated circuits. More particularly, the present invention is directed toward a method for providing self-planarized deposition of high quality dielectric layers for shallow trench isolation.
Semiconductor device geometries continue to decrease in size, providing more devices per unit area on a fabricated wafer. These devices are typically initially isolated from each other as they are built into the wafer, and they are subsequently interconnected to create the specific circuit configurations desired. Currently, some devices are fabricated with feature dimensions as small as 0.18 &mgr;m. For example, spacing between devices such as conductive lines or traces on a patterned wafer may be separated by 0.18 &mgr;m leaving recesses or gaps of a comparable size. A nonconductive layer of dielectric material, such as silicon dioxide (SiO
2
), is typically deposited over the features to fill the aforementioned gaps and insulate the features from other features of the integrated circuit in adjacent layers or from adjacent features in the same layer.
Dielectric layers are used in various applications including shallow trench isolation (STI) dielectric for isolating devices and interlayer dielectric (ILD) formed between metal wiring layers or prior to a metallization process. In some cases, STI is used for isolating devices having feature dimensions as small as under about 0.5 &mgr;m. Planarization of dielectric layers has become increasingly important as the packing densities of semiconductor devices continue to grow.
The planarization issue is described using an example of a typical process for forming a shallow trench isolation (commonly referred as STI integration) as illustrated in
FIGS. 1
a
-
1
g
. In
FIG. 1
a
, a silicon substrate
110
has deposited thereon a pad oxide layer
112
and a nitride layer
114
such as silicon nitride. The nitride layer
114
is typically deposited by low pressure chemical vapor deposition (LPCVD), and serves as an etch stop for chemical mechanical polishing (CMP). Referring to
FIG. 1
b
, a bottom anti-reflective coating (BARC)
116
is formed above the nitride layer
114
for absorbing light reflected from the substrate
110
during photolithography. Typically an organic spin-on glass (SOG), the BARC
116
is needed typically for light having wavelengths of below about 248 nm, including deep ultraviolet (DUV) and far ultraviolet (FUV) light. A photoresist
118
is formed over the BARC
116
and exposed using a mask (not shown) which defines the location of the trenches. The exposed photoresist is then stripped to leave open areas for forming the trenches. Typically, a plasma etch is performed to etch the open areas through the nitride
114
, pad oxide
112
, and silicon substrate
110
to form the trenches
120
, as shown in
FIG. 1
c
. After the remaining photoresist
118
and BARC
116
are removed, a thermal oxide
122
is typically grown on the nitride/pad oxide and on the surfaces of the trenches
120
(trench bottom
124
and trench wall
126
) to repair the plasma damage to the silicon substrate
110
, as illustrated in
FIG. 1
d.
A dielectric layer
128
is then deposited over the thermal oxide
122
to fill the trenches
120
and cover the nitride layer
114
. This dielectric layer
128
is often referred to as a trench oxide filling layer. Typical dielectric layers are formed from oxide materials such as silicon dioxide or silicate glass. As shown in
FIG. 1
e
, the surface profile of the deposited dielectric layer
128
is stepped and generally resembles the shape of the trended substrate
110
. The surface profile is more uniform in dense fields with closely space narrow trenches than in open fields with wide trenches. As seen in
FIG. 1
e
, a step height
130
is formed in the dielectric profile between the dense field
134
and the open field
132
. Because of the step height
130
, it is not practicable to apply CMP directly after the dielectric layer deposition step to planarize the dielectric layer
128
because otherwise a dishing effect in the open field
132
will result with CMP, as seen in
FIG. 1
h
. Instead, a reverse mask and etch procedure is used to etch the extra oxide to obtain a more planar surface profile as illustrated in
FIG. 1
f
. This procedure typically involves the steps of photoresist deposit, reverse masking, cure, etched photoresist removal, etchback, and removal of remaining photoresist. A CMP procedure is then applied to the structure of
FIG. 1
f
to globally planarize the surface of the filled substrate
110
as shown in
FIG. 1
g
. The reverse mask and etch procedure necessitated by the step height effect adds significant cost and complexity (for example, due to the added lithography steps involved) to the planarization procedure.
From the discussion above, it is seen that multiple steps, including additional photolithography steps (which require expensive equipment), are needed to provide STI. However, it is desirable to reduce the number of steps (and related equipment, especially photolithography equipment which requires expensive lenses, light sources, etc.) and to obtain improved results in order to provide a more economic and efficient manufacturing process. For example, one way to obtain improved results is to provide a self-planarized, high quality trench oxide filling layer at a reduced cost.
A number of procedures are known for depositing dielectric layers such as the gap-fill dielectric
128
for the trench oxide filling layer in the example shown in
FIG. 1
e
. One type of process employs O
3
(ozone) and TEOS (tetraethylorthosilicate) for depositing a dielectric film such as silicate glass. Such films deposited are commonly referred to as “O
3
/TEOS films”. O
3
/TEOS processes have a surface sensitivity which increases as the O
3
/TEOS ratio increases. Due to the surface sensitivity, the dielectric deposition rate varies in accordance with the properties of the material of the underlying layer.
It is known to minimize the surface sensitivity by depositing a surface insensitive barrier layer prior to the O
3
/TEOS film deposition. For instance, one known process involves a plasma-enhanced TEOS (PETEOS) deposition, followed by a surface treatment and then a thin cap TEOS layer. This process undesirably requires additional process steps. Another known method is to lower the surface sensitivity by decreasing the O
3
/TEOS ratio. However, lowering the O
3
/TEOS ratio tends to undesirably result in a more porous dielectric film. This is particularly problematic when the dielectric film is used for isolation purposes. One way to address this concern has been to raise the process temperature to above about 500° C., but raising the process temperature is often undesirable. Alternatively, an additional anneal process after the deposition of the trench oxide filling layer and sandwiching PETEOS layers has been used to densify the trench oxide filling layer. This method, however, suffers from the need to perform an extra step.
Instead of minimizing the surface sensitivity, some have utilized the deposition rate dependence of O
3
/TEOS films to perform gap fill for a trenched silicon substrate wherein the side walls of the trench are covered with thermal oxide spacers. Using an atmospheric pressure CVD (APCVD) O
3
/TEOS deposition and an ozone concentration of 5%, it was reported that faster film growth on the bottom silicon than on the side wall spacers precluded void formation to achieve void-free gap fill. Others have investigated the feasibility of forming a planarized intermetal dielectric (IMD) by taking advantage of the surface sensitivity of O
3
/TEOS and similar materials such as O
3
-octamethylcyclotetrasiloiane (OMTC). Researchers have reported difficulties of controlling the different deposition rates to achieve planarity. For instance, significant elevations have been observed at the edges of aluminum metal lines caused by the different deposition rates of the O
3
/TEOS on a TiN ARC layer on top of the alum
Gaillard Frederic
Geiger Fabrice
Applied Materials Inc.
Blakely Sokoloff Taylor a & Zafman
Duda Kathleen
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