Semiconductor device manufacturing: process – Coating with electrically or thermally conductive material – To form ohmic contact to semiconductive material
Reexamination Certificate
2002-01-17
2004-05-11
Lee, Hsien Ming (Department: 2823)
Semiconductor device manufacturing: process
Coating with electrically or thermally conductive material
To form ohmic contact to semiconductive material
C438S634000, C438S637000, C438S692000, C438S717000, C438S736000
Reexamination Certificate
active
06734096
ABSTRACT:
FIELD OF THE INVENTION
This invention relates to semiconductor processing, and more particularly to critical dimension control in deep submicron lithography for fabrication of interconnects in a dual damascene process.
BACKGROUND OF THE INVENTION
Devices with multilevel interconnect structures have become well known in the semiconductor industry. The dual damascene process has proven to be a successful method for building such structures. This process generally involves embedding metal lines in an interlevel dielectric (ILD) layer, and connecting metal layers by metallizing via holes formed in the ILD. In order to improve the electrical performance of the overall device, it is highly desirable that the ILD have a low dielectric constant (k<4). In addition, in very fine-pitch (<300 nm) devices, the lines and via holes must be etched into the ILD with a critical dimension of about 100 nm. This generally requires that the etch be performed with a hardmask. Furthermore, it is often desirable for part of the hardmask to remain on the ILD, to avoid a mask removal process which might damage the ILD; this layer is sometimes called a “residual hardmask” or “permanent hardmask.” Accordingly, the hardmask layer in contact with the low-k ILD should also have a low dielectric constant.
A typical hardmask for formation of lines and vias in the ILD is shown schematically in FIG.
1
A. The ILD
10
is disposed on a barrier layer
1
, which in turn covers the underlying level (not shown). The ILD is generally formed of a polymer such as an organic polyarylene ether thermoset dielectric, or a similar material. The hardmask includes three layers
11
-
13
. Permanent hardmask layer
11
is formed of a low-k material (k<4.5); examples of such materials are organosilicates such as SiCOH (containing Si, C, O and H); SiC; SiC:H; and amorphous Si containing C and H. Layer
11
is covered by layer
12
, typically silicon nitride; thicknesses of layers
11
and
12
are approximately 500 Å and 350 Å respectively. Layer
13
is typically silicon dioxide with a thickness of approximately 1500 Å. The pattern for the metal lines is transferred to layer
13
(“line-level” lithography), resulting in formation of exposed areas
2
in the mask, as shown in FIG.
1
B. Further processing involves depositing a layer of resist
14
which is patterned to define via openings
4
(“via-level” lithography), as shown in FIG.
1
C. This requires that the resist
14
be at least partially planarized over the topography introduced by patterning layer
13
. Layer
13
is also subject to faceting (that is, formation of facets
3
), which leads to loss of critical-dimension control. The fidelity of the pattern transfer is also degraded by roughening of the line edge, caused by deposition thereon of plasma polymers.
Furthermore, as shown in
FIG. 1D
, in subsequent processing the etched lines and via openings are overfilled with metal
16
(often with a liner
15
); the excess metal must then be removed, typically by chemical-mechanical polishing (CMP). If the metal
16
and liner material
15
are removed by CMP at nearly the same rate (for example, when metal
16
is copper and liner
15
is tungsten), the remaining hardmask must also function as a polish stop layer. The thin layer
12
of silicon nitride may not be effective as a CMP stop layer.
There is a need for an improved dual damascene process in which the hardmask structure permits processing with very high fidelity pattern transfer while retaining the advantages of low dielectric constant, and includes an effective CMP stopping layer.
SUMMARY OF THE INVENTION
The present invention addresses the above-described need by providing a dual damascene process using a hardmask structure including a sacrificial hardmask layer and which eliminates at least the oxide layer overlying the low-k dielectric layer.
In accordance with a first aspect of the invention, a method is provided in which three hardmask layers (lower, middle and top) are deposited on a low-k substrate. The top hardmask layer has a thickness less than about 200 Å. A first opening is formed in the top hardmask layer in accordance with a first pattern, thereby exposing a portion of the middle hardmask layer. A second opening is formed in that portion of the middle hardmask layer in accordance with a second pattern and a corresponding opening in the lower hardmask layer, thereby exposing a portion of the substrate. An opening is formed in the substrate, and metal is deposited therein. Excess metal may be deposited over the hardmask and then removed. Finally, the top hardmask layer is removed.
The material of the top hardmask layer may be a refractory metal, a refractory metal nitride, a refractory metal alloy or a conductive Si-based material such as doped Si or doped amorphous Si, and is preferably a refractory metal nitride such as TaN. The middle hardmask layer is preferably SiN. The excess metal may be removed by CMP, with the top hardmask layer having a lower polishing rate than the excess metal being polished.
It should be noted that the process of forming the first opening may include depositing a resist layer on the top hardmask layer and subsequently removing the resist layer therefrom; the middle hardmask layer protects the lower hardmask layer from oxidation during removal of the resist layer.
In accordance with a second aspect of the invention, a method is provided in which a lower hardmask layer and a top hardmask layer are deposited. A protective layer is formed in a region of the lower hardmask layer adjacent to the top surface thereof; this protective layer protects the lower hardmask layer from oxidation when the resist removal is performed. The protective layer may be formed by exposing the lower hardmask layer to a plasma treatment which either forms a protective nitride layer in the top surface region, or densifies the lower hardmask layer in that region. The protective layer has a thickness of approximately 100 Å.
In accordance with an additional aspect of the invention, a method is provided in which a lower hardmask layer and a top hardmask layer are deposited on the substrate. A first opening is formed in the top hardmask layer in accordance with a first pattern, thereby exposing a portion of the lower hardmask layer. This process includes depositing a resist layer on the top hardmask layer and subsequently removing the resist layer therefrom; the resist layer is removed in a non-oxidizing resist strip process, so that oxidation of the lower hardmask layer is avoided. In particular, the resist may be removed in a plasma resist strip process with a reducing chemistry.
It is noteworthy that the top hardmask layer is a thin sacrificial layer which can also serve as a CMP stopping layer, and that oxidation damage to the lower hardmask layer (which generally is of a low-k material) is avoided.
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U.S. application No. 09/550,943, Dalton et al., submitted by applicants.*
U.S. appl. No. 09/550,943, filed Apr. 17, 2000, entitled “Protective Hardmask for Producing Interconnect Structures”, Dalton et al.
Anand Minakshisundaran B.
Armacost Michael D.
Chen Shyng-Tsong
Dalton Timothy J.
Gates Stephen M.
Anderson Jay H.
Karecki Anna
Lee Hsien Ming
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