Semiconductor device manufacturing: process – Coating with electrically or thermally conductive material – To form ohmic contact to semiconductive material
Reexamination Certificate
2001-11-30
2003-02-11
Chaudhuri, Olik (Department: 2813)
Semiconductor device manufacturing: process
Coating with electrically or thermally conductive material
To form ohmic contact to semiconductive material
C438S638000, C438S737000
Reexamination Certificate
active
06518164
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention-relates generally to an etching process for forming a trench of the semiconductor, and in particular to an etching process for forming a contact window or a via hole with high aspect ratio.
2. Description of the Prior Art
As semiconductor devices, such as Metal-Oxide-Semiconductor devices, become highly integrated the area occupied by the device shrinks, as well as the design rule. With advances in the semiconductor technology, the dimensions of the integrated circuit (IC) devices have shrunk to the deep sub-micron range. When the semiconductor device continuously shrinks to the deep sub-micron region, some problems described below are incurred due to the scaling down process.
Dynamic random access memory (DRAM) is applied broadly in the field of integrated circuits devices, and more importantly, in the electronics industry. These devices provide a means of temporary data storage, and they are used in many digital systems, such as computers. Dynamic random access memory (DRAM) with higher capacitance is necessary for the development of the industry. As a result, dynamic random access memory with higher density and capacitance are of great interest and are developed by the related industry. Because intense competition in the Dynamic random access memory (DRAM) marketplace, it is essential that manufacturers reduce the cost of their Dynamic random access memory (DRAM) circuits. To reduce costs and to meet customer expectations for decreasing access times and increasing IC memory size, manufacturers must continually reduce the size of features on the integrated circuit wafer. Such reductions in feature size have brought about much advancement in the art. However, the small geometry presents problems in the predictable manufacture of Dynamic random access memory (DRAM) circuits. How to keep the quality as the size of the device is reduced is now a task for the industry to overcome.
When semiconductor devices of integrated circuit (IC) become highly integrated, the surface of the chips can be not supplied with enough area to make the interconnects. For matching the requirement of interconnects increase when Complementary Metal Oxide Semiconductor (CMOS) devices shrinks, many designs of the integrated circuit have to use dual damascene method. Moreover, it is using the three-dimensional structure of multi-level interconnects at present in the deep sub-micron region, and inter-metal dielectric (IMD) as the dielectric material which is used to separate from each of the interconnects. A conducting wire which connects between the upper and the lower metal layers is called the via plug in semiconductor industry. In general, if an opening which forms in the dielectric layer exposure to devices of the substrate in the interconnects, is called a via. Therefore, the upper and he lower metal layers are electrically connected each other by way of the metal plug in the connect hole or via hole.
In general, in the stacked structure of the dynamic random access memory (DRAM), there is a plurality of dielectric layers
110
with multi-levels on the semiconductor substrate
100
, a plurality of gates
120
are individually located in the plurality of dielectric layers
110
with multi-levels, a plurality of contact windows
130
are individually located on the plurality of gates
120
, and a plurality of via holes
140
are located on the semiconductor substrate
100
, as shown in FIG.
1
A. Because of the levels where the plurality of dielectric layers
110
are formed are different, the deepness for forming the plurality of contact windows
130
are different from each other, and the deepness for forming the plurality of via holes
140
are more deeper. In the semiconductor process, the ratio (H/W) of the trench width and the trench deepness is called “Aspect Ratio”. If the aspect ratio is raised, the trench deepness will be increased or the trench width will be decreased, so that the etching process for forming the trench will be more difficult. For the deep sub-micron technology, the design rule has been scaling down, so that the devices must have the contact windows or via holes with high aspect ratio. Especially, in the dynamic random access memory (DRAM) etching process for forming the contact windows or via holes with high aspect ratio are hard to perform. Furthermore, when the aspect ratio of the contact windows is smaller and smaller, the etching capability of the via holes with high aspect ratio is very important below the process of the dynamic random access memory.
In the conventional etching process, the etchant for etching the trench with a high aspect ratio usually uses two kinds of etching recipes that are C
4
F
8
/O
2
/Ar/CO. Nevertheless, the etching process is terminated during the etching process when forming the trench with a high aspect ratio due to the above etchant with an etching capability that is not enough, so the deepness of the trench has yet to be achieved. This is, the “etching stop” effect, as shown in FIG.
1
B. Especially, when the aspect ratio of the trench is more than
10
, the etching stop effect will be more serious. Moreover, the traditional etchant has higher etching selectivity between different dielectric layers
110
, such as oxide
itride, so the process environment has to be changed to etch through the different dielectric layers
110
, and hence, waste of process cycle time. On the other hand, the traditional etchant has lower etching selectivity to photoresist layer
150
, so that the remainder of the photoresist layer
150
is not enough after the etching process. Hence, loss of the photoresist layer
150
causes the predetermined width of the trench to get out of control, so that the critical dimension of the trench can not be controlled, for example, maybe the predetermined width of the trench becomes more wider, as shown in FIG.
1
C. Although the photoresist layer
150
will be lost during the etching process, still a portion of photoresist layer
150
will remain on the dielectric layer
110
, this issue will always cause a fence of the dielectric layer
110
near the trench, as shown in FIG.
1
D. For the dynamic random access memory (DRAM) with gates that are located on multi-levels, the contact windows and via holes with different aspect ratios are difficult to form by way of using an etching process with one time and traditional etchant. Conventional etching process makes the performance, quality and yield of the devices to worsen, and the process cycle time also increases, hence, additional cost. In accordance with the above description, a new and improved etching method for forming trench is therefore necessary so as to raise the yield and quality of the follow-up process.
SUMMARY OF THE INVENTION
In accordance with the present invention, a method is provided for forming a trench with a high aspect ratio that substantially overcomes the drawbacks of the above mentioned problems that arise from conventional methods.
Accordingly, it is a main object of the present invention to provide an etching process for forming a trench with a high aspect ratio. This invention can utilize the new etching recipe to perform an etching process one time, so as to form the contact windows and the via holes having different aspect ratios and simplify the process step to reduce the process cycle time. Furthermore, the etching capability of the etchant in this invention is very strong to prevent the etching stop effect, so as to form the semiconductor device with a small critical dimension. Therefore, this invention is appropriate for deep sub-micron technology.
Another object of the present invention is to provide a method for forming the contact windows and the via holes with different aspect ratios. The present invention can utilize a new etching recipe to raise the etching selectivity between the dielectric layer and the photoresist layer and reduce the etching selectivity between the dielectric layers from each other, so as to avoid losing the photoresist layer and punch through
Ho Yueh-Feng
Wu Yann-Pyng
Blum David S
Chaudhuri Olik
United Microelectronics Corp.
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