Semiconductor device manufacturing: process – Formation of electrically isolated lateral semiconductive... – Grooved and refilled with deposited dielectric material
Reexamination Certificate
2002-05-15
2003-08-12
Niebling, John F. (Department: 2812)
Semiconductor device manufacturing: process
Formation of electrically isolated lateral semiconductive...
Grooved and refilled with deposited dielectric material
C438S524000, C438S439000
Reexamination Certificate
active
06605517
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to semiconductor processing, and more particularly to a method for minimizing nitride residue on a silicon wafer using a uniform oxide deposition followed by an optimized isolation oxide polish.
BACKGROUND OF THE INVENTION
Transistor memory arrays are typically fabricated on a silicon wafer. The process usually begins by depositing a layer of pad oxide on the wafer substrate. Typically, the pad oxide is 150-250Å thick. A nitride mask is then deposited over the pad oxide and etched to define active regions on the silicon substrate. An isolation technology is then used to create isolation regions between the active regions to electrically isolate the active regions from one another. In shallow trench isolation (STI) for example, shallow trenches are etched into the silicon substrate in the openings in the nitride mask between the active regions. A liner oxidation process is then performed in the trenches in which a thin layer of oxide is grown. Next, an oxide such as TEOS (tetraethyl orthosilicate) or HDP (high-density plasma) is deposited over the silicon substrate and is then polished back so that it remains only in the trenches, its top surface level with the nitride mask. After the oxide is etched back, the nitride mask is stripped to expose the pad oxide. Thereafter, layers of polysilicon are patterned to define stacked gate structures and word lines for the semiconductor device.
Unfortunately, the conventional processes for depositing and polishing the oxide, and for removing the nitride from the wafer may result in the formation of faulty devices. The oxide is deposited on the wafer using a low-pressure chemical vapor deposition system (LPCVD) in which gasses continuously flow into a reaction chamber holding the wafer where deposition occurs. The LPCVD deposition, however, results in a non-uniform layer of oxide on the wafer due to an edge to center temperature gradient and depletion of reactive gasses in the chamber.
FIG. 1A
is a top view of a silicon wafer
10
after oxide deposition with cross-sectional views showing the center area of the wafer
10
and the edge area of the wafer
10
, respectively. The dotted lines in the top view are graphical representations of trench isolation areas
12
beneath the layer of isolation oxide
14
, which is shown in the cross-sectional views deposited over the nitride mask
16
to fill the trenches
12
. During oxide deposition, more of the oxide gas reacts on the surface of the wafer
10
along the edge area, while less of the oxide gas reaches the center area of the wafer
10
, resulting in the oxide being approximately 100-200Å thicker in the edge area of the wafer
10
compared to the center area. This difference in oxide thickness is shown graphically by the arrows. For a 200 mm wafer, for example, the edge area of the wafer where the oxide becomes non-uniform may be 5-20 mm in size, while the center area may be 195-180 mm in size.
After the isolation oxide
14
is deposited, the oxide
14
is polished down to the top level of the nitride
16
. Once goal of the polishing process is to cease polishing just before the nitride layer is encountered, which in the ideal case would leave a thin skin of oxide
14
above the nitride. The next step is to remove this thin skin of oxide
14
by way of an HF dip etch. Because of the non-uniformity in the thickness of the oxide
14
, however, more oxide
14
will remain in the edge area of the wafer
10
than in the center after polishing, and the HF dip etch will fail to remove all of the oxide
14
in the edge area of the wafer
10
.
After the dip etch, the nitride is stripped from the wafer
10
with a bath of hot phosphoric acid and, which does not attack oxide
14
.
FIG. 1B
is a top view of the wafer
10
after the nitride strip. Because the acid does not affect the oxide
14
, if there is any oxide
14
remaining on top of the nitride
16
, the nitride
16
will not be removed under these areas, leaving nitride residue
18
in the edge area of the wafer
10
. The problem with nitride residue
18
is that it will block formation of the subsequent transistor structures and cause defects in the memory array.
Accordingly what is needed is method for minimizing nitride residue on a silicon wafer. The present invention addresses such a need.
SUMMARY OF THE INVENTION
The present invention provides a method for reducing nitride residue from a silicon wafer during semiconductor fabrication. The wafer includes a nitride mask defining active regions and isolation regions wherein the isolation regions are formed by trenches. The method includes providing an optimized oxide deposition process in which a temperature gradient of a CVD chamber is improved by performing the following steps. First, at least one silicon wafer is placed into the chamber on a quartz boat having an increased slot size, preferably at least 6 mm. Second, the quartz boat is centered in approximately a center of the chamber so that the wafer is located in a center section of the chamber to avoid the temperature gradient at the ends of the chamber, such that when oxide gas is injected onto the wafer, an oxide layer having a substantially uniform thickness is formed on the wafer. The method further includes performing an optimized polishing process on the oxide wherein the oxide is polished down to approximately a level of the nitride, but where more of the oxide is removed from the edge area of the wafer than in the center area. Thereafter, the nitride is stripped from the wafer.
According to the present invention, because all of the oxide is removed, substantially all of the nitride can be removed from the wafer during the nitride strip, thereby minimizing nitride residue and increasing the reliability of the resulting semiconductor devices.
REFERENCES:
patent: 4355974 (1982-10-01), Lee
patent: 6146928 (2000-11-01), Ishiguro et al.
patent: 6296710 (2001-10-01), Allen et al.
Achuthan Krishnashree
Bhakta Jayendra D.
Hui Angela
Advanced Micro Devices , Inc.
Isaac Stanetta
Niebling John F.
Winstead Sechrest & Minick P.C.
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