Patent Application
20070238027
1. Field of the Invention
The present invention relates to a method for generating alignment marks and related mask thereof, and more particularly, to a method for generating alignment marks capable of being utilized in different exposure machines and related mask thereof.
2. Description of the Prior Art
In the semiconductor manufacturing field, a photolithography method is commonly used for manufacturing a semiconductor device. In the photolithography method, a photoresist is formed on a semiconductor wafer. The photoresist is exposed by using a photomask and then developed for forming a circuit pattern. Next, a layer, which is located under the photoresist, can be etched such that a needed circuit pattern can be formed. In order to produce an electronic device, a plurality of the above-mentioned processes should be performed. Taking the liquid crystal display (LCD) for example, five photolithography processes must be performed through five masks such that circuit patterns of the gate electrode (GE) layer, semiconductor (SE) layer, source/drain (SD) layer, contact hole (CH) layer, and pixel electrode (PE) layer can be formed.
As known by those skilled in the art, in the exposing step, the photomask must be correctly aligned with the semiconductor substrate. Alignment marks, which are formed in the photomask and in the wafer, are used for the alignment. That is, before performing the photolithography process, the mask must first be well aligned with the substrate so that the circuit pattern can be correctly imaged on the substrate. The alignment mark, as it is called, is utilized to support the aforementioned alignment operation of the mask and the substrate. In general, the gate electrode layer (first layer) mask not only comprises the circuit pattern corresponding to the electronic device, but also comprises pre-defined alignment marks. Therefore, during the gate electrode layer exposure operation, the alignment marks are formed on the substrate through the gate electrode layer mask. In addition, the following masks (such as the above-mentioned semiconductor layer, source/drain layer, contact hole layer, and pixel electrode layermasks) also comprise predetermined alignment marks. Therefore, before exposure operations are performed on the semiconductor layer, source/drain layer, contact hole layer, and pixel electrode layer, the alignment marks of the semiconductor layer, source/drain layer, contact hole layer, and pixel electrode layer masks are utilized to align the alignment marks, previously formed on the substrate. This can ensure the accuracy of the exposure operations.
However, the positions where the alignment marks are formed directly influences the results of the entire semiconductor manufacturing process. Please refer to
We assume that the alignment marks defined by the gate electrode layer mask are exposed on the predetermined positions 110 shown in
On the other hand, we assume that the alignment marks of the gate electrode layer mask are exposed on the predetermined positions 120. However, the alignment marks are formed more widely than the predetermined positions 120 because of the changing shape. Therefore, when the following exposure operations of the following layers are being performed, the alignment marks of the masks are narrower than the alignment marks of the substrate. This makes the exposed circuit pattern (as the dotted line 160 shown in
As is disclosed, different positions of the alignment marks causes the difference (as the difference D shown in
Unfortunately, LCD manufacturer may utilize two different exposure machines to produce the LCDs because of manufacturing efficiencies. For example, the LCD manufacturer can use one exposure machine (ex: Canon exposure machine) to perform the exposure operations of multiple masks, and use another exposure machine (ex: Nikon exposure machine) to perform the exposure operations of the other masks.
Please refer to
It is therefore one of the primary objectives of the claimed invention to provide a method for generating alignment marks capable of being utilized in two different exposure machines and related mask thereof, to solve the above-mentioned problem of the prior art.
According to an exemplary embodiment of the claimed invention, a method for generating alignment marks on a substrate is disclosed. The method comprises: providing a mask, where the mask defines at least one alignment mark set, and the alignment mark set comprises a first alignment mark capable of being utilized in a first exposure machine and a second alignment mark capable of being utilized in a second exposure machine; and utilizing the mask to generate the first alignment mark and the second alignment mark on the substrate in the first exposure machine; wherein the first alignment mark is substantially adjacent to the second alignment mark.
According to an exemplary embodiment of the claimed invention, a mask capable of generating alignment marks on a substrate is disclosed. The mask comprises: at least one alignment mark set, where each alignment mark set comprises: a first alignment mark capable of being utilized in a first exposure machine; and a second alignment mark capable of being utilized in a second exposure machine; wherein the first alignment mark is substantially adjacent to the second alignment mark.
The claimed invention alignment mark set comprises adjacent alignment marks, which respectively corresponds to different exposure machines. Therefore, when the LCD is being produced, the overlap situations can be reduced because the distance between alignment marks are reduced. In other words, the claimed invention can decrease the errors of circuit patterns to raise the yield, and makes it more possible to simultaneously utilize two exposure machines to produce the LCD.
These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.
In the following disclosure, we still utilize the LCD as an embodiment of the present invention. Please refer to
Because the first alignment mark 310 is substantially adjacent to the second alignment mark 320, when the gate electrode layer mask 300 is utilized to perform the exposure operation, the first alignment mark 310 and the second alignment mark 320 are formed adjacent on the glass substrate. As mentioned previously, the position difference between the first alignment mark 310 and the second alignment mark 320 causes the different overlap situations of the circuit pattern. For example, the present invention can minimize the positional difference between the first alignment mark 310 and the second alignment mark 320 because two alignment marks 310 and 320 are adjacent. Therefore, when the other masks are utilized to perform the exposure operations, because the first alignment mark 310 and the second alignment mark 320 almost correspond to the same location on the glass substrate, the exposed circuit patterns do not have so many errors. Therefore, the present invention can efficiently reduce the error of the overlap situation of the circuit patterns.
Please refer to
In the above disclosure, the LCD is only utilized as an embodiment, not a limitation of the present invention. That is, the present invention does not limit the application fields. The present invention method can be utilized to simultaneously use two different exposure machines to manufacture all kinds of electronic products. Therefore, the glass substrate is also utilized as an embodiment here. The present invention can be implemented in a wafer; this also obeys the spirit of the present invention.
Furthermore, the present invention can be utilized in different exposure machines such that they can cooperate to produce a needed electronic device. This also obeys the spirit of the present invention.
In contrast to the prior art, the present invention alignment mark set comprises adjacent alignment marks, which respectively corresponds to different exposure machines. Therefore, when the LCD is being produced, the overlap situations can be reduced because the distance between alignment marks are reduced. In other words, the present invention can decrease the errors of circuit patterns to raise the yield, and makes it more possible to simultaneously utilize two exposure machines to produce the LCD.
Those skilled in the art will readily observe that numerous modifications and alterations of the device and method may be made while retaining the teachings of the invention. Accordingly, the above disclosure should be construed as limited only by the metes and bounds of the appended claims.
