Semiconductor device manufacturing: process – Coating with electrically or thermally conductive material – To form ohmic contact to semiconductive material
Reexamination Certificate
2001-11-21
2004-04-13
Whitehead, Jr., Carl (Department: 2813)
Semiconductor device manufacturing: process
Coating with electrically or thermally conductive material
To form ohmic contact to semiconductive material
C438S790000
Reexamination Certificate
active
06720251
ABSTRACT:
FIELD OF THE INVENTION
This invention relates to the manufacture of semiconductor devices as components of integrated circuits, specifically to processes for photolithography in which anti-reflective coatings are used to increase the accuracy of the photolithographic processing steps.
BACKGROUND OF THE INVENTION
In a dual damascene architecture, wiring patterns are etched into a dielectric, or insulating layer. See, e.g., Handbook of semiconductor interconnection technology, edited by Schwartz et al., Marcel Dekker 1998; and Copper—Fundamental Mechanisms for Microelectronic Applications, Murarka et al., Wiley 2000. The conductor material (typically copper) is then inlaid into those features. There are two types of features used for this purpose: trenches, which form the actual wiring template; and vias, which make connection to the metal level below. Creating such structures requires two passes through the photo-lithography process. Either the vias are formed first and then the trenches or vice versa.
The dielectric stack requirements for dual damascene include the primary insulating layer and a thin copper diffusion barrier or selective metal barrier. Additional layers may be included to facilitate fabrication, such as an intermediate etch stop, hard mask, etc.
An anti-reflective layer (or ARL) is often used for photolithographic processes. The ARL minimizes the total reflection of light from layers under the photoresist and the interface between the photoresist layer and the underlying layer. By adjusting the thickness, t, refractive index, n, and extinction coefficient, k, of the ARL film, as shown in
FIG. 1
, a destructive interference can be obtained in the photoresist with equivalent intensities of incident and reflective light. As a result, zero reflectivity can be reached under ideal conditions. Thus, an ARL improves the accuracy of pattern transfer when the photoresist is developed.
FIG. 2
show a schematic diagram of a simplified lithography process flow of the via-first dual damascene applications. Typically, anti-reflective layer
18
is deposited onto underlying layer
12
, which is being patterned over the other film stack. Photoresist
10
is then spun onto top of the anti-reflective layer. See, FIG.
2
(
a
). The process proceeds through (b) via photoresist development to (c) via etch to (d) via photoresist removal and cleaning to (e) or (e
1
) trench photoresist coating and (f) or (f
1
) trench photoresist development. The exposed portion of the photoresist layer
10
is removed when photoresist layer
10
is developed, yielding the clean vertical walls shown in FIG.
2
(
b
) when UV radiation is incident on area of the top surface of photoresist layer
10
, exposing a portion of the photoresist layer
10
. When developed, the trench should be patterned properly and yielded vertical wall, as shown in FIG.
2
(
f
).
However, this identity in pattern after the development step is not always realized. More specifically, silicon dioxide (SiO
2
) historically has been used as the primary interconnect insulating layer. With device geometries shrinking and speeds increasing, the trend now is towards insulating materials with lower dielectric constants (low-k). One of the most persistent difficulties associated with the integration of the low-k film has been its interaction with photoresists used with deep UV radiation (“DUV”, i.e., radiation having a wavelength of 248 nm and below). Low-k films often contain a small amount of nitrogen, present in the form of NH
x
(amines). The NH
x
species can diffuse rapidly through low-k dielectric films, such as would be used in layer
12
. Such groups are known to react in a detrimental fashion with DUV photoresists by neutralizing the photo-acid catalyst. The result is footing or bridging of the printed features. These footings narrow the opening in the photoresist which results in poor pattern transfer to the underlying layers. See, FIG.
3
.
To alleviate this phenomenon, a hard mask could be incorporated on top of the low-k film. This approach is very costly and is limited to hard masks that are barriers to the diffusion of amines (i.e., low k hard masks would not be suitable.) Moreover, the use of a hard mask will be effective only for single layer lithography; e.g., printing vias for via-first dual damascene, or trenches in the case of trench-first. However, after formation of those features into the dielectric, DUV resist would once again come in contact with low-k film during the next pass through lithography. The result would be regions of undeveloped resist in the second pass lithography features. For example, in the case of via-first patterning, the appearance of “mushrooms” or “rivet heads” over the vias (also filled with resist) in the trench regions. A DUV photoresist “mushroom” is illustrated schematically in FIG.
2
(f
1
) and demonstrated in a SEM picture shown in FIG.
4
.
Organic layers have been commonly used as ARLs for I-line radiation (i.e., radiation having a wavelength of 365 nm), although inorganic layers can also be used. Layers of inorganic materials such as silicon oxynitride are often used for deep UV radiation. For a discussion of the use of deep UV ARLs, see T. Ogawa et al.; “Practical Resolution Enhancement Effect By New Complete Anti-Reflective Layer In KrF Excimer Laser Lithography”; Optical/Laser Microlithography; Session VI; Vol. 1927 (1993), incorporated herein by reference. For a general discussion of the use of ARLs, see T. Perara, “Anti-Reflective Coatings: An Overview”; Solid State Technology, Vol. 37, No. 7; pp. 131-136 (1995), which is incorporated herein by reference.
There is a need for a simpler approach to deposit an ARL film with elimination of the photoresist footing problem and photoresist poisoning (mushroom) problem in dual damascene processes. It would be desirable for the ARL film to be optically and thermally stable, to be chemically inert to the environments to which it is exposed, and to be applicable for use with any wavelength of UV radiation. In addition, the ARL film should have good adhesion to commonly used materials and have good mechanical and structural integrity. Finally, it would be desirable to provide a single continuous process for producing the ARL film with acceptable uniformity across the wafer .
SUMMARY OF THE INVENTION
In accordance with this invention, a substantially nitrogen-free ARL is provided. The ARL is compatible with chemically amplified photoresists found in lithography processes using DUV radiation. It is effective in eliminating footing and inhibits the photoresist poisoning of the second layer of lithography in dual damascene applications.
The ARL can be formed using chemical vapor deposition (CVD), including, for example, plasma enhanced chemical vapor deposition (PECVD), low-pressure chemical vapor deposition, (LP-CVD), high-density plasma chemical vapor deposition (HDP-CVD), or similar methods under process conditions that are designed to provide an ARL having the desired properties. These properties principally include thickness (t), refractive index (n), and extinction coefficient (k), with the values of n and k being a function of the wavelength of the radiation.
The ARL is formed by introducing source gases or liquids comprising silicon, oxygen, carbon, and hydrogen into the reaction chamber of the CVD unit. In a particularly preferred embodiment, the ARL is formed from carbon dioxide and silane. The process conditions or parameters of this invention are principally the flow rate of the reactant gases, the volumetric ratio of the gaseous components, the deposition pressure, the deposition temperature, and the rate at which radio frequency (RF) power is applied in a PECVD unit (per unit area of the surface of the wafer or other substrate on which the ARL is formed).
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Karim M. Zlaul
Li Ming
Mountsier Tom
Schravendijk Bart van
Tian Jason
Beyer Weaver & Thomas LLP
Dolan Jennifer M
Jr. Carl Whitehead
Novellus Systems Inc.
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