An apparatus for plasma treatment of a non-conductive hollow substrate, including a plurality of ionization energy sources disposed adjacent to each other all along the part of the substrate to be treated. The apparatus also includes a processor to sequentially power the plurality of ionization ene
An apparatus for plasma treatment of a non-conductive hollow substrate, including a plurality of ionization energy sources disposed adjacent to each other all along the part of the substrate to be treated. The apparatus also includes a processor to sequentially power the plurality of ionization energy sources from a radio frequency power source. Each ionization energy source includes two parts sandwiching the substrate. The ionization energy sources can be capacitively or inductively coupled plasma sources.
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The invention claimed is: 1. A method for plasma treatment of a non-conductive elongated hollow substrate having a length, a transverse dimension transverse to the length and an internal cavity, by an apparatus for plasma treatment including a plurality of ionization energy sources disposed adjacen
The invention claimed is: 1. A method for plasma treatment of a non-conductive elongated hollow substrate having a length, a transverse dimension transverse to the length and an internal cavity, by an apparatus for plasma treatment including a plurality of ionization energy sources disposed adjacent to each other along said length, each ionization energy source including a first and a second source part that face each other and are dimensioned to produce there between a uniform field covering at least said transverse dimension, said method comprising the steps of: a) placing the substrate to be treated in between said first and second source parts of said ionization energy sources; b) injecting a process gas inside the cavity of said substrate, said process gas containing a precursor to be consumed for plasma treatment of said substrate; and c) maintaining pressure inside the cavity of said substrate within a predetermined range; and d) powering from radio frequency power supply means the ionization energy sources sequentially, thus selectively creating plasma inside the cavity of said substrate at a location corresponding to the respective powered ionization energy source, said radio frequency power supply means delivering power at a frequency around 10 kHz to 100 MHz; wherein said step b) of injecting the process gas inside the cavity of said substrate is repeated at least before the powering of each ionization energy source to replace consumed precursor so as to maintain a constant precursor concentration each time plasma is created. 2. The method for plasma treatment according to claim 1, wherein said step b) is commanded such that process gas is injected in a pulsed fashion so that the injection of process gas is synchronized with the powering of each of the ionization energy sources. 3. The method for plasma treatment according to claim 1, wherein, in said step b) of injecting a process gas inside the substrate, the process gas is continuously injected inside the substrate at a constant precursor rate. 4. The method for plasma treatment according to claim 1, wherein the plurality of ionization energy sources are capacitively coupled plasma sources, said first and said second source parts of each source respectively being first and second electrodes that face each other and are dimensioned to produce there between the uniform field covering at least said transverse dimension, wherein the uniform field is a uniform electric field. 5. The method for plasma treatment according to claim 1, wherein the plurality of ionization energy sources are inductively coupled plasma sources, said first and said second source parts of each source respectively being first and second coil arrangements that face each other and are dimensioned to produce there between a uniform magnetic field covering at least said transverse dimension. 6. The method for plasma treatment according to claim 1, wherein the ionization energy sources are powered in a pulsed fashion. 7. The method for plasma treatment according to claim 1, wherein the plurality of ionization energy sources are disposed at each side of the substrate according to an array of two dimensions. 8. The method for plasma treatment according to claim 1, wherein in said step d), the plurality of ionization energy sources are powered by a single radio frequency power source. 9. The method for plasma treatment according to claim 1, wherein injecting the gas inside the substrate includes injecting the gas from a first end of the substrate, and wherein evacuation of the inside of the substrate is performed via an opening on a second end of the substrate opposite the first end of the substrate. 10. An apparatus for plasma treatment of a non-conductive elongated hollow substrate having a length, a transverse dimension transverse to the length and an internal cavity, said apparatus comprising: generation means for generating a plasma inside the cavity of said substrate, said generation means comprising a plurality of ionization energy sources disposed adjacent to each other along said length, each ionization energy source comprising a first and a second source part that face each other and are dimensioned to produce there between a uniform field covering at least said transverse dimension; radio frequency power supply means delivering power at a frequency around 10 kHz to 100 MHz, each ionization energy source being connected to said power supply means through a corresponding supply line, each supply line comprising a switch; processing means connected to each said switch for sequentially powering the plurality of ionization energy sources from radio frequency power supply means and for selectively creating plasma inside the cavity of said substrate at a location corresponding to the respective powered ionization energy source; a process gas source for supplying a process gas containing a precursor to be consumed for plasma treatment of said substrate; a gas flow controller connected to said processing means in order to command a flow of process gas flowing from said process gas source into the cavity of said substrate; said processing means being programmed to control said switches and said gas flow controller so that said ionization energy sources are sequentially powered and process gas is injected inside the cavity of said substrate at least before the powering of each ionization energy source to replace consumed precursor so as to maintain a constant precursor concentration each time plasma is created. 11. The apparatus according to claim 10, wherein the radio frequency power supply means is of a pulse generator type for powering the ionization energy sources in a pulsed fashion. 12. The apparatus according to claim 10, said processing means being programmed for commanding said gas flow controller for injecting process gas in a pulsed fashion so that the injection of process gas is synchronized with the powering of each ionization energy source. 13. The apparatus according to claim 10, wherein the plurality of ionization energy sources are capacitively coupled plasma sources, said first and said second source parts of each source respectively being first and second electrodes that face each other and are dimensioned to produce there between a uniform electric field covering at least said transverse dimension. 14. The apparatus according to claim 10, wherein the plurality of ionization energy sources are inductively coupled plasma sources, said first and said second source parts of each source respectively being first and second coil arrangements that face each other and are dimensioned to produce there between a uniform magnetic field covering at least said transverse dimension. 15. The apparatus according to claim 14, wherein each of said first and second coil arrangements comprises a combination of a magnetic core and an inductor for producing through the substrate a homogenized magnetic flux perpendicular to a direction of a substrate length all over the area of the substrate which is covered by said first and second coil arrangement. 16. The apparatus according to claim 15, further comprising a plasma chamber provided with two oppositely facing electromagnetic field admission windows made of dielectric material said first and second coil arrangements being oppositely located on an outer surface of the first and second windows respectively, said first and second coil arrangements being connected to a power supply line such that a current of a same direction flows simultaneously in the first and second coil arrangements. 17. The apparatus according to claim 16, wherein said first and second coil arrangements each comprise an inductor having a serpentine form. 18. The apparatus according to claim 16, wherein said plurality of ionization energy sources are disposed at each side of the substrate according to an array of two dimensions. 19. The apparatus according to claim 10, wherein said radio frequency power supply means comprise a single radio frequency power source for powering said plurality of ionization energy sources. 20. The apparatus according to claim 10, wherein said processing means receives a gas flow value signal from said gas flow controller to monitor process gas flow and said processing means is programmed to correct for process gas flow irregularity by modulating one or more parameters of powering said ionization energy sources.
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