EP1733411A1 - Apparatus and method for plasma treating an article - Google Patents
Apparatus and method for plasma treating an articleInfo
- Publication number
- EP1733411A1 EP1733411A1 EP04716162A EP04716162A EP1733411A1 EP 1733411 A1 EP1733411 A1 EP 1733411A1 EP 04716162 A EP04716162 A EP 04716162A EP 04716162 A EP04716162 A EP 04716162A EP 1733411 A1 EP1733411 A1 EP 1733411A1
- Authority
- EP
- European Patent Office
- Prior art keywords
- plasma
- chamber
- source
- anode
- cathode
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Withdrawn
Links
Classifications
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
- H01J37/32—Gas-filled discharge tubes
- H01J37/32009—Arrangements for generation of plasma specially adapted for examination or treatment of objects, e.g. plasma sources
- H01J37/32357—Generation remote from the workpiece, e.g. down-stream
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
- H01J37/32—Gas-filled discharge tubes
- H01J37/32009—Arrangements for generation of plasma specially adapted for examination or treatment of objects, e.g. plasma sources
- H01J37/32055—Arc discharge
Definitions
- the invention relates to an apparatus for generating a substantially uniform plasma. More particularly, the invention relates to an apparatus for generating a substantially uniform plasma for treating an article. Even more particularly, the invention relates to an apparatus that is capable of generating a controllable, adjustable plasma for treating an article.
- Plasma sources are used to provide a variety of surface treatments for a number of articles. Examples of such surface treatments include deposition of various coatings, plasma etching, and plasma activation of the surface. The characteristics of the plasma treatment process are strongly affected by the operating parameters of the plasma source.
- ETP expanding thermal plasma
- ETP expanding thermal plasma
- cathode-to-anode distance may change over time due to erosion of the cathode, or cathode voltage or operating pressure may change.
- cathode-to-anode distance may change over time due to erosion of the cathode, or cathode voltage or operating pressure may change.
- disruption of the process and disassembly of the plasma source are usually required.
- An array of multiple plasma sources may be used to coat larger substrate areas.
- the individual plasmas generated by each of the plasma sources in the array should have the same characteristics. In practice, however, source-to-source variation in plasma characteristics and, consequently, in the resulting plasma treatment, is commonly observed. A significant amount of the variability is related to the previously described variations in the individual plasma sources.
- the present invention meets these and other needs by providing an apparatus that generates at least one plasma that is stable and adjustable in real time.
- the apparatus includes multiple plasma sources that can either be “tuned” in real time to generate plasmas that are similar to each other or, conversely, "detuned” to generate dissimilar plasmas.
- the apparatus may be used to provide plasma treatment - such as, but not limited to, coating, etching, heating, lighting or, illumination, and activation - for an article.
- the invention also provides a plasma source in which operating parameters are adjustable in real time. Methods of providing such plasmas and treating an article using such plasmas are also disclosed.
- one aspect of the invention is to provide an apparatus for generating a substantially controllable plasma.
- the apparatus comprises: at least one plasma ⁇ source, the plasma source comprising a plasma chamber in which the substantially controllable plasma is generated, at least one cathode and an anode disposed in the plasma chamber, the at least one cathode and the anode being separated by a gap, the gap being adjustable, a power source coupled to the anode and the at least one cathode for providing a voltage across the anode and the at least one cathode, a plasma gas inlet for introducing a gas for generating the plasma (hereinafter referred to as a "plasma gas”) from a plasma gas source into the plasma chamber at a plasma gas flow rate, and a sensor for monitoring conditions within the plasma chamber; and a second chamber in fluid communication with the plasma chamber through an exit port, wherein the second chamber is maintained at a second pressure that is less than a first pressure in the plasma chamber, and wherein the substantially controllable plasma flows from the
- a second aspect of the invention is to provide a plasma source for generating a substantially controllable plasma.
- the plasma source comprises: a plasma chamber in which the substantially controllable plasma is generated; an anode disposed at a first end of the plasma chamber, the first end having an exit port through which the substantially controllable plasma exits the plasma chamber; at least one adjustable cathode disposed in the plasma chamber, wherein the at least one adjustable cathode is movable to establish a gap between the anode and the at least one adjustable cathode; a power source coupled to the anode and the at least one adjustable cathode for providing a voltage across the anode and the at least one adjustable cathode; a plasma gas inlet for introducing a plasma gas from a plasma gas source into the plasma chamber at a plasma gas flow rate; and at least one sensor for detecting and monitoring conditions within the plasma chamber.
- a third aspect of the invention is to provide an apparatus for generating a substantially controllable expanding thermal plasma.
- the apparatus comprises: at least one expanding thermal plasma source, the at least one expanding thermal plasma source comprising: a plasma chamber in which the substantially controllable plasma is generated; an anode; at least one adjustable cathode disposed in the plasma chamber, wherein the at least one adjustable cathode is movable to establish a gap between the anode and the at least one adjustable cathode; a power source coupled to the anode and the at least one adjustable cathode for providing a voltage across the anode and the at least one adjustable cathode; a plasma gas inlet for introducing a plasma gas from a plasma gas source into the plasma chamber at a plasma gas flow rate; and at least one sensor for detecting and ⁇ onitoring conditions within the plasma chamber; and a second chamber in fluid communication with the plasma chamber through an exit port, wherein the second chamber is maintained at a second pressure that is less than a first pressure in the plasma chamber
- a fourth aspect of the invention is to provide a method for generating a substantially controllable plasma.
- the method comprises the steps of: providing at least one plasma source, the at least one plasma source comprising: a plasma chamber; an anode; at least one adjustable cathode disposed in the plasma chamber; a power source coupled to the anode and the at least one adjustable cathode; a plasma gas inlet; and at least one sensor; providing a plasma gas through the plasma gas inlet to the plasma chamber in each of the at least one plasma source; generating a plasma in the plasma chamber; monitoring at least one parameter within the plasma chamber; and controlling the plasma, wherein the plasma is controlled by adjusting conditions within the plasma chamber, based upon the monitoring of the at least one parameter.
- a fifth aspect of the invention is to provide a method for treating an article using a substantially controllable expanding thermal plasma.
- the method comprises the steps of: providing at least one expanding thermal plasma source, wherein the at least one expanding thermal plasma source comprises: a plasma chamber; an anode; at least one adjustable cathode disposed in the plasma chamber; a power source coupled to the anode and the at least one adjustable cathode; a plasma gas inlet; and at least one sensor; providing a plasma gas through the plasma gas inlet to the plasma chamber in each of the at least one plasma source; generating a plasma in the plasma chamber; monitoring at least one parameter within the plasma chamber; and controlling the plasma, wherein the plasma is controlled by adjusting conditions within the plasma chamber, based upon the monitoring of the at least one parameter; forming an expanding thermal plasma by expanding the plasma through an exit port into a second , chamber in fluid communication with the plasma chamber, wherein the second chamber contains the article and is maintained at a second pressure that is less than a first pressure in said plasma chamber; and imping
- FIGURE 1 is a schematic representation of an apparatus for generating a substantially controllable plasma
- FIGURE 2 is a plot of plasma chamber pressure as a function of cathode length, measured at a constant flow rate of argon gas into the plasma chamber;
- FIGURE 3 is a plot of cathode voltage as a function of cathode length, measured at a constant flow rate of argon gas into the plasma chamber;
- FIGURE 4 is a plot of cathode voltage and plasma chamber pressure as a function of time
- FIGURE 5 is a plot of deposition profiles of silicon carbide films deposited using multiple plasma sources in both the tuned and detuned states.
- FIGURE 6 is a plot of individual Taber delta haze values for an abrasive resistant silicone coating as a function of substrate location and position with respect to the individual ETP sources.
- First plasma source 102 comprises a plasma chamber 104, a cathode 106, and an anode 108. Cathode 106 is disposed within, and extends into, plasma chamber 104.
- plasma source 102 may include multiple cathodes 106.
- Anode 108 is located at one end of plasma chamber 102.
- An exit port 118 provides fluid communication between plasma . chamber 104 and' second chamber 140. The substantially controllable plasma generated within plasma chamber 104 exits plasma chamber 104 through exit port 118 and enters second chamber 140.
- exit port 118 may comprise an orifice formed in anode 108.
- exit port may comprise at least one "floating" (i.e., electrically insulated from both cathode 106 and anode 108) cascade plate 122 separating anode 108 from the rest of plasma chamber 102.
- exit port 118 may be located in a floating wall -in one of plasma chamber 102 and second chamber 140.
- a gas for generating the plasma (hereinafter referred to as a "plasma gas") is injected into plasma chamber 104 through at least one plasma gas inlet 114.
- the plasma gas may comprise at least one inert or non-rea,ctive gas, such as, but not limited to, a noble gas (i.e., He, Ne, Ar, Xe, Kr).
- the plasma gas may comprise a reactive gas, such as, but , not limited to, hydrogen, nitrogen, oxygen, fluorine, or chlorine.
- Flow of ,the plasma gas may be controlled by a flow controller, such as a mass flow controller, located between a plasma gas source (not shown) and the at least one plasma gas inlet 114.
- a first plasma is generated within plasma chamber 104 by injecting the plasma gas into plasma chamber 104 through the at least one plasma gas inlet 114 and striking an arc between cathode 106 and anode 108.
- the voltage needed to strike an arc between cathode 106 and anode 108 is provided by power source 1 12.
- power source 112 is an adjustable DC power source that provides up to about 100 amps of current at a voltage of up to about 50 volts.
- Second chamber 140 is maintained at a second chamber pressure by a vacuum system (not shown), which is substantially less than a first plasma chamber pressure.
- second chamber 140 is maintained at a pressure of less than about 1 torr (about 133 Pa) and, preferably, at a pressure of less than about 100 millitorr (about 0. 133 Pa), while plasma chamber 104 is maintained at a pressure of at least about 0.1 atmosphere (about 1 .OlxlO 4 Pa).
- first plasma passes through exit port 118 and expands into second chamber 140.
- Second chamber 140 is adapted to contain an article 160 that is to be treated with the plasmas produced by apparatus 100.
- plasma treatment of article 160 comprises injecting at least one reactive gas into the plasma produced by apparatus 100 and depositing at least one coating on a surface of article 160.
- the surface of article 160 upon which the at least one plasma impinges may be either planar or non-planar.
- Apparatus 100 is capable of providing other plasma treatments in which at least one plasma impinges upon a surface of article 160, such as, but not limited to, plasma etching at least one surface of article 160, heating article 160, lighting or illuminating article 160, or functionalizing (i.e., producing reactive chemical species) a surface of article 160.
- the characteristics of the plasma treatment process are strongly affected by the operating parameters of the plasma source.
- operating parameters are the operating pressure within the plasma source, plasma resistance, the potential across the cathode and anode, the plasma current, and the cathode-to-anode distance.
- the plasmas generated by at least one of first plasma source 102 and second plasma source 202 are expanding thermal plasmas (also referred to hereinafter as "ETP").
- ETP expanding thermal plasmas
- a plasma is generated by ionizing the plasma source gas in the arc generated between at least one cathode 106 and anode 108 to produce a positive ion and an electron.
- argon plasma is generated, argon is ionized, forming argon ions (Ar + ) and electrons (e ⁇ ).
- the plasma is then expanded into a high volume at low pressure, thereby cooling the electrons and positive ions.
- the plasma is generated in plasma chamber 104 and expanded into second chamber 140 through exit port 118.
- second chamber 140 is maintained at a substantially lower pressure than the plasma chamber 104.
- the positive ion and electron temperatures are approximately equal and in the range of about 0.1 eN (about 1000 K).
- the electrons have a sufficiently high temperature to substantially affect the chemistry of the plasma.
- the positive ions typically have a temperature of about 0.1 eV, and the electrons have a temperature of about 1 eV, or 10,000 K, or higher. Consequently, the electrons in the ETP are too cold and thus have insufficient energy to cause direct dissociation of any gases that may be introduced into the ETP. Such gases may instead undergo charge exchange and dissociative recombination reactions with the electrons within the ETP.
- FIGS. 2 and 3 are plots of plasma chamber pressure and cathode voltage as a function of cathode length, respectively.
- gap 110 decreases as the cathode length increases.
- the cathode-to-anode distance was systematically varied and the data was collected using a constant flow rate of argon gas into the plasma chamber.
- the pressure of the plasma decreases with decreasing cathode-to-anode distance.
- the voltage needed to sustain the plasma decreases with decreasing cathode-to-anode distance, as illustrated in Fjgure 3.
- Changes - or "drift" - in cathode-to-anode may occur during operation of a plasma source. Drift may be caused by erosion of either the cathode or anode, deposition of material on either the cathode or anode, mechanical settling or seating of plasma source components, and thermal expansion of plasma source components. Variation of cathode voltage and plasma pressure as functions of time (expressed in Figure 4 as the number of experiments run under the same conditions) are shown in Figure 4. It is understood that some factors - such as deposition of material on either the cathode or anode - may cause drift in a direction opposite that shown in Figure 4.
- the present invention provides a plasma source 102 in which gap 110 (i.e., cathode- to-anode distance) is adjustable in real time to a desired distance in response to selected conditions within plasma chamber 104, such as, but not limited to, plasma pressure, cathode voltage, plasma current, and plasma gas flow rate.
- At least one sensor 116 monitors a d detects any change in such conditions within plasma chamber 104.
- the sensor(s) selected for use in plasma source 102 depends upon the property to be monitored.
- Non-limiting examples of the at least one sensor 116 that may be used monitor conditions within plasma chamber 104 include: a pressure sensor, such as a transducer, in fluid communication with plasma chamber 104; a voltmeter (or any similar voltage measurement device) for measuring and detecting cathode voltage; and an ammeter for measuring and detecting plasma current. Any change detected by the at least one sensor 116 is fed to a controller, which then adjusts gap 110 by changing the position of one of cathode 106 and anode 108 to maintain the selected conditions within desired ranges.
- plasma source 102 includes at least one adjustable cathode 106.
- Gap 110 may be set to a predetermined distance by moving cathode 106.
- changes in plasma chamber pressure or cathode voltage, as detected and monitored by the at least one sensor 116 are indicative of changes in gap 110.
- Cathode drift may, for example, be indicated by shifts or changes in cathode voltage and plasma chamber pressure.
- Plasma chamber pressure data obtained during statistical process control as feedback for example, may be used to control .gap 110. Compensation of cathode drift may be achieved during operation of plasma source 102 by movement of adj ustable cathode 106 in response to input by the at least one sensor 116 to maintain gap 110 at the selected distance. Variation due to cathode drift of the plasma generated by plasma source 104 is thus eliminated or significantly reduced by such adjustment of cathode 106.
- Such movement of the adjustable cathode 106 may be performed in real time either manually or by a controller.
- Non-limiting examples of situations in which plasma properties may be altered during operation include deposition of multiple layers on a single substrate or performing multiple plasma treatments of a single article.
- the ability to adjust gap 110 in real time permits the properties of the plasma generated by plasma source 102 to be modified in a controllable fashion without disassembly of plasma source 102.
- Movement of adjustable cathode 1'06 may be accomplished by a pressure means coupled to the movable cathode 106.
- pressure means include a pressure plate coupled to a rear portion of adjustable cathode 106 by either set screws or a screw drive.
- gap ,110 may be increased or decreased by either applying or releasing pressure to the pressure plate, or gap 110 may be maintained at a constant value as adjustable cathode 106 erodes during operation of plasma source 102 by applying pressure plate as needed.
- pressure means may comprise a pneumatic drive coupled to adjustable 'cathode 106. The pneumatic drive may increase, decrease, or maintain gap 110 at a selected value - as conditions dictate - by moving adjustable cathode 106 accordingly.
- plasma source 102 further includes a screw or worm drive for moving adjustable cathode 106, thereby adjusting gap 110.
- adjustable cathode 106 comprises a wire, and movement of adjustable cathode 106 to either increase, decrease, or maintain gap 110 at a selected value is achieved by coupling a wire feed to adjustable cathode 106.
- Adjustable cathode 106 in one embodiment, is movable in a direction that is normal to cascade plate 122.
- the longitudinal axis of adjustable cathode 106 is concentric with exit port 118.
- adjustable cathode 106 is movable in a direction parallel to cascade plate 122.
- cathode 106 is movable and anode 108 is fixed during operation of plasma source 102. In other embodiments, however, gap 110 may be adjusted by providing first plasrria source 102 with a movable anode 108. Movement of anode 108 may be accomplished by mechanisms similar to those previously described for providing movement of adjustable cathode 106.
- First plasma source 102 may also include both a movable cathode 106 and a movable anode 108.
- second plasma source 202 includes features corresponding to those of first plasma source 102, which are described herein.
- plasma source 202 includes cathode 206, anode 208, gap 210, at least one plasma gas inlet 214, at least one sensor 216, exit port 218, and cascade plate 222.
- the voltage needed to strike an arc between cathode 206 and anode 208 is provided by either power source 112 or a separate power source.
- the characteristics (e.g., coating thickness, degree of etching or activation) of a region treated by a single plasma source generally exhibit a profile having a Gaussian distribution about the axis of the plasma source.
- uniformity may be promoted by positioning the individual plasma sources such that the resulting Gaussian distributions overlap.
- the profile, as well as the width and height of the distributions are dependent in part upon the characteristics of the plasmas that are used to treat the substrate.
- the characteristics of each of the plasmas are in turn dependent upon the conditions - such as cathode voltage, plasma gas pressure and cathode-to-anode distance (gap 110) - used to generate the plasmas within the individual plasma sources.
- conditions within first plasma source 104 - and, consequently, the first plasma produced by first plasma source 102 - are adjustable with respect to conditions within plasma chamber 204 and second plasma, and vice versa.
- first plasma source 102 and second plasma source 202 may be "tuned" to eliminate or minimize variation between the first plasma and the second plasma by setting at least one of plasma pressures, cathode voltages, and gaps 110, 210 of first plasma source 102 and second plasma source 202 to be equal to each other.
- first plasma source 102 and second plasma source 202 may be advantageous, for example, for depositing a coating having a substantially uniform profile of at least one selected property over a large surface area of a planar substrate.
- first plasma source 102 and second plasma source 202 may be "de-tuned" by moving adjustable cathodes 106', 206 to provide gaps 110, 210 of unequal size, thereby producing a first plasma and second plasma that are dissimilar with respect to each other. Detuning may be desirable, for example, for plasma treating a non-planar substrate. In such instances, the working distance (i.e., the distance between a plasma source and the substrate surface) for first plasma source 102 may differ from the working distance for second plasma source 202. At the point at which they impinge on the surface of article 160, the properties of the first plasma (generated by first plasma source 102) would consequently differ from those of the setond plasma (generated by second plasma source 202).
- Adjustable cathodes 106, 206 or, in some embodiments, adjustable anodes 108, 208 to provide gaps 110, 210 of unequal size to produce first and second plasmas that have essentially the same properties at their respective points of impingement upon the surface of article 160.
- the characteristics of the plasma generated by first plasma source 102 also depends upon the pressure of the plasma gas within plasma chamber 104 and the voltage (or potential) of cathode 106.
- the characteristics of the plasma may also be controlled by adjusting at least one of the pressure of the plasma gas within plasma chamber 104 and the voltage of cathode 106.
- Plasma gas pressure may be monitored by the at least one sensor 116 and adjusted accordingly.
- One means of adjusting the plasma gas pressure is by controlling the flow of plasma gas into plasma chamber 104 through plasma gas inlet 114.
- Means for controlling the flow of plasma gas into plasma chamber 104 include, but are not limited to, needle valves and mass flow controllers.
- the cathode voltage (or potential) may be similarly monitored by the at least one sensor 116, and adjusted by adjusting power supply 1 12 accordingly. It is understood that, in those embodiments having a second plasma source 202, the characteristics of the plasma generated by second plasma source 202 may be similarly controlled by adjusting at least one of the plasma gas pressure within plasma chamber 204 and the voltage of cathode 206 in response to input provided by the at least one sensor 216.
- the present invention permits at least one of the pressure of the plasma gas within plasma chamber 104 and the cathode voltage of cathode 106 to be adjustable with respect to the plasma gas pressure within plasma chamber 20.4 and the cathode voltage of cathode 206, respectively.
- conditions within plasma chamber 104 - and thus the first plasma produced by first plasma source 102 - are adjustable with respect to conditions within plasma chamber 204 and the second plasma produced by second plasma source 202, and vice versa.
- the first plasma generated by first plasma source may be either "tuned” to eliminate or minimize variation between the first plasma and the second plasma or "detuned" to be dissimilar with respect to each other.
- Tuning of the first plasma and the second plasma may be achieved by adjusting at least one of plasma pressures and cathode voltages of first plasma source 102 and second plasma source 202 to be equal to each other.
- the first and second plasma may be detuned by adjusting at least one of plasma pressures and cathode voltages of first plasma source 102 and second plasma source 202 to be dissimilar with respect to each other.
- Plasma pressures within plasma chambers 104, 204 may be monitored by the at least one sensors 116, 216, respectively.
- the plasma pressures within each of plasma chambers 104, 204 may be adjusted in response to the input provided by the at least one sensors 116, 216.
- cathode voltages of cathodes 106, 206 may be monitored by the at least one sensors 116, 216, respectively, and adjusted with respect to each other by adjusting power supply 112 accordingly.
- FIG. 4 An example of such tuning and detuning of the plasmas produced by multiple plasma sources is shown in Figure 4.
- the profiles of a-Si x C y :H films deposited on a substrate by injecting vinyltrimethylsilane (VTMS) into plasmas generated by multiple ETP sources are plotted as a function of lateral position on the substrate.
- the film profiles correspond to the properties - such as, but not limited to, temperature, density, cross-sectional area, and reactant concentration - of the plasmas that are used to deposit the films.
- the squares in Figure 4 represent the film profile that is obtained when the two sources that are detuned; i.e., operated at different plasma pressures and cathode voltages.
- the dissimilar plasmas produce a profile in which the thickness of the deposited exhibits a significant variation.
- the diamonds in Figure 4 represent the film profile that is 'obtained when the pressures and voltages of the two sources have been tuned to be equal. The resulting profile exhibits less variation than that obtained using detuned plasma sources.
- Another aspect of the invention is to provide an article having at least one coating disposed on a surface of the article, wherein the at least one coating is deposited by the method described herein using apparatus 100.
- the at least orie coating is substantially uniform and has a selected property that exhibits a variation of less than about 10% across the surface of the article.
- the selected property of the at least one coating may be one of coating thickness, abrasion resistance, ultraviolet radiation absorbance, infrared radiation reflectivity, modulus, hardness, oxygen permeability, water permeability, adhesion, surface energy, thermal conductivity, and electrical conductivity.
- the at least one coating may comprise an abrasion-resistant coating, an ultraviolet filtering coating, an infrared reflective coating, an oxygen- or moisture- , barrier coating, an anti-reflective coating, a conductive coating, interlayers, an adhesion layer and combinations thereof.
- Example 1 The advantages and salient features of the present invention are illustrated by the following example: Example 1
- An abrasive resistant silicone (SiO- . C,,) coating was deposited on a polycarbonate LEXAN® substrate using an array of expanding thermal plasma (ETP) sources.
- ETP expanding thermal plasma
- Each of the ETP sources included an adjustable cathode of the present invention.
- the ETP plasma sources were tuned by equalizing the pressures within the respective plasma chambers.
- the coating was formed by injecting oxygen (O 2 ) and octamethyltetracyclosiloxane (D.4) into each of the ETPs.
- the resulting coating had a thiclcness of about 2 microns.
- the abrasion resistance of the coating was determined by a 1000 cycle Taber abrasion test. A plot of the individual Taber Delta haze values as a function of substrate location and position with respect to the individual ETP sources is shown in Figure 6.
- the coating exhibited a uniform 2% increase in haze with a standard deviation of 0.6% across the large area substrate.
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- Physics & Mathematics (AREA)
- Engineering & Computer Science (AREA)
- Plasma & Fusion (AREA)
- Chemical & Material Sciences (AREA)
- Analytical Chemistry (AREA)
- Chemical Vapour Deposition (AREA)
Abstract
Description
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Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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PCT/US2004/006234 WO2005096345A1 (en) | 2004-03-01 | 2004-03-01 | Apparatus and method for plasma treating an article |
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EP1733411A1 true EP1733411A1 (en) | 2006-12-20 |
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EP04716162A Withdrawn EP1733411A1 (en) | 2004-03-01 | 2004-03-01 | Apparatus and method for plasma treating an article |
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WO (1) | WO2005096345A1 (en) |
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CN103305812A (en) | 2013-06-08 | 2013-09-18 | 上海和辉光电有限公司 | Top electrode device |
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US4780591A (en) * | 1986-06-13 | 1988-10-25 | The Perkin-Elmer Corporation | Plasma gun with adjustable cathode |
DE19716236C2 (en) * | 1997-04-18 | 2002-03-07 | Deutsch Zentr Luft & Raumfahrt | Plasma torch device |
US6797336B2 (en) * | 2001-03-22 | 2004-09-28 | Ambp Tech Corporation | Multi-component substances and processes for preparation thereof |
US6948448B2 (en) * | 2001-11-27 | 2005-09-27 | General Electric Company | Apparatus and method for depositing large area coatings on planar surfaces |
US20040040833A1 (en) * | 2002-08-27 | 2004-03-04 | General Electric Company | Apparatus and method for plasma treating an article |
-
2004
- 2004-03-01 EP EP04716162A patent/EP1733411A1/en not_active Withdrawn
- 2004-03-01 WO PCT/US2004/006234 patent/WO2005096345A1/en active Application Filing
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