Method of making an anti-reflection structure for a...

Semiconductor device manufacturing: process – Coating with electrically or thermally conductive material – To form ohmic contact to semiconductive material

Reexamination Certificate

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Details

C438S952000, C257S288000

Reexamination Certificate

active

06524945

ABSTRACT:

BACKGROUND OF THE INVENTION
(a) Field of the Invention
The present invention relates to an anti-reflection structure for a conductive layer in a semiconductor device and, more particularly, to an anti-reflection structure suited for forming a conductive layer pattern having an accurate width in a semiconductor device.
(b) Description of the Related Art
With the development of higher integration of semiconductor devices, for example in a MOSFET device, it has become more and more important to form an interconnect pattern having an accurate width, regardless of the situation wherein the line width and the line pitch have become smaller and smaller.
In a MOSFET device, the gate electrodes are generally configured using a photolithographic and etching technique wherein a mask pattern is accurately transferred onto a conductive layer by using an exposure light. In order to prevent the transfer error during the photolithographic step using the exposure light, an anti-reflection layer is generally formed on the conductive layer to be patterned.
Example of using the anti-reflection layer will be described with reference to the process for patterning gate electrodes in DRAM memory cells.
FIG. 1
shows a sectional view of a DRAM memory cell. The memory cell generally designated by numeral
10
includes a silicon substrate
12
, an isolation film
14
formed thereon for isolation of device areas, a MOSFET
16
formed in each device area, and a capacitor
18
overlying the MOSFET
16
. The MOSFET
16
includes a gate electrode
24
including a gate electrode layer
20
, and a silicon nitride layer
22
formed thereon. A side wall structure
26
is formed on both the sides of the gate electrode
24
.
A contact plug
28
is disposed in contact with a diffused region (not shown) formed in the surface region of the silicon substrate
12
. The gate electrode layer
20
is connected to a word line (not shown). The silicon nitride layer
22
acts as an etch stopper during the etching step for forming a through-hole receiving therein the contact plug
28
. The gate electrode
24
is also disposed on the isolation region
14
for convenience of the fabrication process.
The capacitor
18
overlies the MOSFET
16
with an intervention of an interlayer dielectric film
30
. The capacitor
18
includes a capacitor contact
32
penetrating the interlayer dielectric film
30
to be in contact with the contact plug
28
, a bottom electrode
34
in contact with the capacitor contact
32
, and a top electrode
38
opposing the bottom electrode
34
with an intervention of a capacitor insulator film
36
.
FIGS. 2A
to
2
F show consecutive steps for fabrication of the DRAM memory cell
10
of FIG.
1
. As shown in
FIG. 2A
, an element isolation film
14
is formed on a silicon substrate
12
for isolation of device areas, followed by consecutively forming thereon a gate electrode layer
20
, a first silicon nitride layer
22
, an anti-reflection layer
40
including a lower silicon oxide nitride film
40
a
and an upper silicon oxide film
40
b
, and a photoresist film
42
.
Subsequently, a gate mask pattern is transferred onto the photoresist film
42
, followed by patterning thereof to form an etching mask
44
, as shown in FIG.
2
B. By using the etching mask
44
, as shown in
FIG. 2C
, the silicon oxide film
40
b
, the silicon oxide nitride film
40
a
, silicon nitride layer
22
and the gate electrode layer
20
are selectively etched for patterning, thereby forming a gate electrode structure
46
.
A second nitride film is then formed on the entire surface including the gate electrode structure
46
, followed by selective etching of the second nitride film to form side walls
26
on the gate electrode structure
46
, and etching of the silicon nitride layer
40
b
and the silicon oxide nitride film
40
a
to remove the same from the gate electrode structure
46
, as shown in FIG.
2
D. Thereafter, an interlayer dielectric film
48
made of silicon oxide is deposited and subjected to CMP thereof to obtain a smoothed top surface.
Then, the interlayer dielectric film
48
is selectively etched using a self-alignment contact etching technique having a high selective ratio between the first silicon nitride layer
22
and the interlayer dielectric film
48
, whereby through-holes
49
are formed in the interlayer dielectric film
48
, as shown in
FIG. 2E
, to expose the surface regions of the silicon substrate. In the self-alignment contact etching step, the first silicon nitride layer
22
acts an etch stop layer.
Then, a conductive layer is deposited on the entire surface to fill the through-holes
49
and etched-back to obtain contact plugs
28
as shown in FIG.
2
F.
Subsequently, as shown in
FIG. 1
, an interlayer dielectric film
30
is deposited, followed by a known process for forming the capacitor contact
32
and the capacitor
18
.
In the above conventional anti-reflection structure, the anti-reflection layer
40
including the silicon oxide nitride film
40
a
and the silicon nitride layer
40
b
is formed on the gate electrode layer
20
with an intervention of the silicon nitride layer
22
, as detailed in FIG.
3
A. As an alternative structure, the anti-reflection layer
40
may be formed between the gate electrode layer
20
and the silicon nitride layer
22
, such as shown in FIG.
3
B.
In the conventional anti-reflection structure as described above as well as the alternative structure, the thickness of the anti-reflection layer
40
is determined based on several factors including the materials for the gate electrode layer
20
, the thickness of the silicon nitride layer
22
, and the types and materials for the photoresist film. Thus, it is difficult to determine the optimum value for the thickness for the anti-reflection layer, whereby the conventional anti-reflection layer cannot demonstrate a sufficient function during the exposure.
In other words, there is a problem in the conventional technique in that an inaccurate pattern is transferred onto the photoresist film due to the adverse effects of the reflected light generated during the exposure of the photoresist film. The inaccurate pattern involves irregularity of the gate width in the DRAM memory cells and of the line width in general semiconductor devices.
More specifically, in the anti-reflection structure of
FIG. 3A
, assuming that the design thickness of the silicon nitride layer
22
is 2000 angstroms, for example, the silicon oxide nitride film
40
b
should have a thickness of 500 angstroms in order to obtain a minimum variation for the gate width.
In this case, i.e., wherein the silicon oxide nitride film
40
b
has a thickness of 500 angstroms, the variation of the gate width may be suppressed to within 8 nm if the silicon nitride layer
22
has an exact thickness of 2000 angstroms. However, if the silicon nitride layer
22
has an actual thickness of 1800 or 2200 angstroms, the gate width variation amounts up to 40 nm. A typical case for this example is shown in
FIG. 4A
, wherein the top surface of the gate electrode layer
20
has an irregularity to cause a depression on the silicon oxide film
40
b
acting as the underlying layer for the photoresist film
44
. This in turn causes an irregularity of the pattern width of the photoresist film
44
, wherein the pattern width increases at the depression and decreases at the elevation of the underlying layer.
In the anti-reflection structure of
FIG. 3B
, assuming similarly that the design thickness of the silicon nitride layer
22
is 2000 angstroms, the silicon oxide nitride film
40
b
should have a thickness of 500 angstroms in order to obtain a minimum variation for the gate width.
In this case, i.e., wherein the silicon oxide nitride film
40
b
has a thickness of 500 angstroms, the variation of the gate width may be suppressed to within 8 nm if the silicon nitride film layer
22
has an exact thickness of 2000 angstroms. However, if the silicon nitride layer
22
has an actual thickness of 1800 or 2200 angstroms, the gate width variation amounts up to 50 nm or 5

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