This application claims priority of Taiwanese application no. 100108913, filed on Mar. 16, 2011.
1. Field of the Invention
This invention relates to a microwave plasma deposition device, more particularly to a microwave plasma deposition device for forming a silicon film with a relatively large area.
2. Description of the Related Art
Referring to
The main chamber 11 has a chamber room 201, and a pressure and a gas atmosphere inside the chamber room 201 can be varied such as by vacuum-pumping or introducing gases. The support 12 is disposed on a bottom side of the chamber room 201 for supporting an article (not shown) to be coated. The microwave plasma generator 14 is disposed at a top side of the chamber room 201, and is used for activating a plasma-forming gas supplied to the chamber room 201 to generate a plasma.
For coating a film on an article using the conventional microwave plasma deposition device, the article is disposed on the support 12, the vacuum degree and the gas atmosphere inside the chamber room 201 are adjusted to predetermined levels, followed by introducing a microwave using the microwave plasma generator 14 to ignite a plasma. Thereafter, a precursor supplied to the vicinity of the support 12 interacts with the plasma to form a film on the article.
However, when coating a relatively large film on an article, especially when coating a silicon film to form a solar cell panel using the conventional microwave plasma deposition device, the flatness and fineness of the coated film is not sufficient. This is because the film is formed by interaction between the plasma and the precursor in the vicinity of the support 12, and because particles are likely to be formed in the plasma while the plasma travels to the support 12 due to phenomena, such as reversal of the excited state of the plasma to an initial state thereof, recombination of ions and electrons, etc.
Therefore, the conventional microwave plasma deposition device needs further improvement.
Therefore, an object of the present invention is to provide a microwave plasma deposition device that can overcome the aforesaid drawbacks associated with the prior art.
According to researches, the dissociation energy for a silicon compound (for example, the energy for dissociation of SiCl4 into Si ions) need not be very high. When the silicon compound serves as a precursor to interact with a low energy portion of the plasma (such as a remote plasma, or a corona plasma, especially when it is used to form a large silicon film, the flatness and fineness of the film can be improved.
Accordingly, a microwave plasma deposition device of this invention comprises:
a main chamber;
a support disposed in the main chamber for supporting an article to be coated;
a resonance chamber fluidly connected to the main chamber and disposed opposite to the support;
a microwave plasma generator disposed in the resonance chamber for generating a plasma to travel to the support;
a separation cover unit disposed in the main chamber to cover the support and to define a deposition space within the main chamber and around the support, and
including a plurality of plasma through holes that connect fluidly the deposition space with a remaining part of the main chamber to permit the plasma to enter the deposition space; and
a precursor supplying device for supplying a precursor to the deposition space.
Other features and advantages of the present invention will become apparent in the following detailed description of the preferred embodiment of the invention, with reference to the accompanying drawings, in which:
Referring to
The main chamber 31 is an upright chamber. The pressure and the atmosphere inside the main chamber 31 may be varied in a known manner, such as by vacuum-pumping or introducing gases.
The support 32 is disposed in a bottom part of the main chamber 31 for supporting an article (not shown) to be coated.
The resonance chamber 33 is fluidly connected to a top side of the main chamber 31, and is disposed oppositely to the support 32. The resonance chamber 33 includes a perforated partition wall 331 having a plurality of through holes 403 and dividing the resonance chamber 33 into a gas inlet region 404 and a plasma generation region 405. The plasma generation region 405 is connected fluidly to the gas inlet region 404 through the through holes 403 of the perforated partition wall 331, and is connected fluidly to the main chamber 31 oppositely of the gas inlet region 404. In an embodiment, the resonance chamber 33 confines an interior space having a radius of 65 mm and a height of 153 mm. The through holes 403 of the perforated partition wall 331 have a through-hole diameter of 3˜5 mm, and are arranged regularly and spaced apart by a distance of 8˜12 mm.
The microwave plasma generator 34 is disposed in the resonance chamber 33 for generating a plasma to travel to the support 32. The microwave plasma generator 34 includes a gas supplying unit 341 for introducing a plasma-forming gas into the gas inlet region 404, and an annular waveguide 342 connected to the plasma generation region 405 to emit microwave to interact with the plasma-forming gas. The annular waveguide 342 may have a rectangular cross section. The radius of the annular waveguide 342 may be about 110 mm. The cooling device 35 includes a plurality of cooling jackets 351 surrounding the main chamber 31 and the resonance chamber 33 for circulation of cooling water. With the cooling device 35, generation of high temperature heat, due to a high power needed to ignite the plasma under an atmosphere of 400˜760 torr, may be prevented.
Further referring to
The surrounding wall 360 surrounds the support 32. The upper wall 361 is disposed on top of the surrounding wall 360. The lower wall 362 is disposed below the upper wall 361 and is spaced apart from the support 32. The plasma through holes 408 extend through the upper and lower walls 361, 362, and connect fluidly the deposition space 407 with a plasma travelling space 406 in a remaining part of the main chamber 31 to permit the plasma, especially a remote plasma that travels through the plasma travelling space 406, to enter the deposition space 407. The precursor receiving space 409 is disposed between the upper and lower walls 361, 362 and is connected to the precursor supplying device 37 that is used for supplying a precursor. The precursor through holes 410 extend through the lower wall 362, and connect fluidly the precursor receiving space 409 to the deposition space 407. Accordingly, the precursor from the precursor supplying device 37 can be supplied to the deposition space 407 through the precursor receiving space 409 and the precursor through holes 410 to interact with the remote plasma. The plasma through holes 408 have a through-hole size of 3˜5 mm, and are spaced apart by a distance of 8˜12 mm. The precursor through holes 410 have a through-hole size of 1˜3 mm, and are spaced apart by a distance of 5˜12 mm. The plasma through holes 408 and the precursor through holes 410 are arranged in annular rows in the lower wall 362. The annular rows of the plasma through holes 408 alternate with the annular rows of the precursor through holes 410. Each row of the plasma through holes 408 is spaced apart from an adjacent row of the precursor through holes 410 by a distance of 5˜12 mm.
The precursor supplying device 37 includes a precursor source 371 for supplying the precursor, and a conduit 372 for connecting the precursor source 371 with the precursor receiving space 409.
For growing a film using the microwave plasma deposition device of this invention, an article is disposed on the support 32, and the main chamber 31 is vacuumed to have a predetermined atmospheric pressure thereinside. Thereafter, a predetermined plasma-forming gas is supplied from the gas supplying unit 341 to the gas inlet region 404, and then travels to the plasma generation region 405 through the through holes 403 of the perforated partition wall 331. The plasma-forming gas in the plasma generation region 405 is ignited by the microwave emitted from the annular waveguide 342 to generate a plasma. The plasma travels toward the support 32. When the plasma travels to the separation cover unit 36, only the remote plasma that has a relatively low energy can pass through the plasma through holes 408 and into the deposition space 407. In the meantime, the precursor from the precursor source 371 is supplied to the precursor receiving space 409 via the conduit 372, and then flows to the deposition space 407 through the precursor through holes 410. The remote plasma and the precursor interact with each other in the deposition space 407 to form a film on the article on the support 32. The coated film has improved flatness and fineness, and the microwave plasma deposition device of this invention is suitable for forming a relatively large area film on a solar cell panel.
While the present invention has been described in connection with what is considered the most practical and preferred embodiment, it is understood that this invention is not limited to the disclosed embodiment but is intended to cover various arrangements included within the spirit and scope of the broadest interpretations and equivalent arrangements.
Number | Date | Country | Kind |
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100108913 | Mar 2011 | TW | national |