Abstract: In one implementation, a method is provided capable of etching a wafer to form devices including a high-k dielectric layer. The method includes etching an upper conductive material layer in a first plasma chamber with a low cathode temperature, transferring the wafer to a second chamber without breaking vacuum, etching a high-k dielectric layer in the second chamber, and transferring the wafer from the second chamber to the first plasma chamber without breaking vacuum. A lower conductive material layer is etched with a low cathode temperature in the first chamber. In one implementation, the high-k dielectric etch is a plasma etch using a high temperature cathode. In another implementation, the high-k dielectric etch is a reactive ion etch.

Abstract: Disclosed herein is a cleaning method useful in removing contaminants from a surface of a coating which comprises an oxide or fluoride of a Group III B metal. Typically the coating overlies an aluminum substrate which is present as part of a semiconductor processing apparatus. The coating typically comprises an oxide or a fluoride of Y, Sc, La, Ce, Eu, Dy, or the like, or yttrium-aluminum-garnet (YAG). The coating may further comprise about 20 volume % or less of Al2O3.

Abstract: Methods for forming anisotropic features for high aspect ratio application in etch process are provided in the present invention. The methods described herein advantageously facilitates profile and dimension control of features with high aspect ratios through a sidewall passivation management scheme. In one embodiment, sidewall passivations are managed by selectively forming an oxidation passivation layer on the sidewall and/or bottom of etched layers. In another embodiment, sidewall passivation is managed by periodically clearing the overburden redeposition layer to preserve an even and uniform passivation layer thereon. The even and uniform passivation allows the features with high aspect ratios to be incrementally etched in a manner that pertains a desired depth and vertical profile of critical dimension in both high and low feature density regions on the substrate without generating defects and/or overetching the underneath layers.

Abstract: Methods for forming anisotropic features for high aspect ratio application in etch process are provided in the present invention. The methods described herein advantageously facilitates profile and dimension control of features with high aspect ratios through a sidewall passivation management scheme. In one embodiment, sidewall passivations are managed by selectively forming an oxidation passivation layer on the sidewall and/or bottom of etched layers. In another embodiment, sidewall passivation is managed by periodically clearing the overburden redeposition layer to preserve an even and uniform passivation layer thereon. The even and uniform passivation allows the features with high aspect ratios to be incrementally etched in a manner that pertains a desired depth and vertical profile of critical dimension in both high and low feature density regions on the substrate without generating defects and/or overetching the underneath layers.

Abstract: In one implementation, a method for etching a flash memory high-k gate stack on a workpiece is provided which includes etching a conductive material layer in a low temperature plasma chamber and etching a high-k dielectric layer in a high temperature plasma chamber. The workpiece is transferred between the low temperature plasma chamber and the high temperature plasma chamber through a vacuum transfer chamber connecting the low temperature plasma chamber and the high temperature plasma chamber. In one embodiment, an integrated etch station for etching a high-k flash memory structure is provided, which includes an etch chamber configured for plasma etch processing of a conductive material layer connected via a transfer chamber to an etch chamber configured for plasma etch processing of a high-k dielectric layer.

Abstract: In one implementation, a method is provided capable of etching a wafer to form devices including a high-k dielectric layer. The method includes etching an upper conductive material layer in a first plasma chamber with a low cathode temperature, transferring the wafer to a second chamber without breaking vacuum, etching a high-k dielectric layer in the second chamber, and transferring the wafer from the second chamber to the first plasma chamber without breaking vacuum. A lower conductive material layer is etched with a low cathode temperature in the first chamber. In one implementation, the high-k dielectric etch is a plasma etch using a high temperature cathode. In another implementation, the high-k dielectric etch is a reactive ion etch.

Abstract: A fluorine-free integrated process for plasma etching aluminum lines in an integrated circuit structure including an overlying anti-reflection coating (ARC) and a dielectric layer underlying the aluminum, the process being preferably performed in a single plasma reactor. The ARC open uses either BCl3/Cl2 or Cl2 and possibly a hydrocarbon passivating gas, preferably C2H4. The aluminum main etch preferably includes BCl3/Cl2 etch and C2H4 diluted with He. The dilution is particularly effective for small flow rates of C2H4. An over etch into the Ti/TiN barrier layer and part way into the underlying dielectric may use a chemistry similar to the main etch. A Cl2/O2 chamber cleaning may be performed, preferably with the wafer removed from the chamber and after every wafer cycle.

Abstract: Methods for forming anisotropic features for high aspect ratio application in etch process are provided in the present invention. The methods described herein advantageously facilitates profile and dimension control of features with high aspect ratios through a sidewall passivation management scheme. In one embodiment, sidewall passivations are managed by selectively forming an oxidation passivation layer on the sidewall and/or bottom of etched layers. In another embodiment, sidewall passivation is managed by periodically clearing the overburden redeposition layer to preserve an even and uniform passivation layer thereon. The even and uniform passivation allows the features with high aspect ratios to be incrementally etched in a manner that pertains a desired depth and vertical profile of critical dimension in both high and low feature density regions on the substrate without generating defects and/or overetching the underneath layers.

Abstract: Methods for forming anisotropic features for high aspect ratio application in etch process are provided in the present invention. The methods described herein advantageously facilitates profile and dimension control of features with high aspect ratios through a sidewall passivation management scheme. In one embodiment, sidewall passivations are managed by selectively forming an oxidation passivation layer on the sidewall and/or bottom of etched layers. In another embodiment, sidewall passivation is managed by periodically clearing the overburden redeposition layer to preserve an even and uniform passivation layer thereon. The even and uniform passivation allows the features with high aspect ratios to be incrementally etched in a manner that pertains a desired depth and vertical profile of critical dimension in both high and low feature density regions on the substrate without generating defects and/or overetching the underneath layers.

Abstract: Disclosed herein is a gas distribution plate for use in a gas distribution assembly for a processing chamber, where the gas distribution plate is fabricated from a solid yttrium oxide-comprising substrate, which may also include aluminum oxide. The gas distribution plate includes a plurality of through-holes, which are typically crescent-shaped. Through-holes which have been formed in the solid yttrium oxide-comprising substrate by ultrasonic drilling perform particularly well. The solid yttrium oxide-comprising substrate typically comprises at least 99.9% yttrium oxide, and has a density of at least 4.92 g/cm3, a water absorbency of about 0.02% or less, and an average grain size within the range of about 10 ?m to about 25 ?m. Also disclosed herein are methods for fabricating and cleaning the yttrium oxide-comprising gas distribution plate.

Abstract: Disclosed herein is a cleaning method useful in removing contaminants from a surface of a coating which comprises an oxide or fluoride of a Group III B metal. Typically the coating overlies an aluminum substrate which is present as part of a semiconductor processing apparatus. The coating typically comprises an oxide or a fluoride of Y, Sc, La, Ce, Eu, Dy, or the like, or yttrium-aluminum-garnet (YAG). The coating may further comprise about 20 volume % or less of Al2O3.

Abstract: In one implementation, a method is provided for etching a high k dielectric material in a plasma etch reactor, the method comprising plasma etching the high k dielectric material with a first plasma gas reactant mixture having BCl3. The high k dielectric material may include Al2O3 in a stack having a silicon layer. The etching may include supplying a passivation gas, for example C2H4, and may further include supplying a diluent gas such as a noble gas, for example He. In some implementations, the etching may be performed with a reactive ion etch process.

Abstract: A method of cleaning process residues formed on surfaces in a chamber during processing of a substrate in the chamber includes first and second steps. In a first cleaning step, a first energized cleaning gas having a first chlorine-containing gas and oxygen is provided in the chamber and then exhausted. In a second cleaning step, a second energized cleaning gas having a second chlorine-containing gas and oxygen is provided in the chamber and then exhausted.

Abstract: A process for etching a substrate and removing etch residue deposited on the surfaces in the etching chamber has two stages. In the first stage, an energized first process gas is provided in the chamber, and in the second stage, an energized second process gas is provided in the chamber. The energized first process gas comprises SF6 and Ar, the volumetric flow ratio of SF6 to other components of the first process gas being from about 5:1 to about 1:10. The energized second process gas comprises CF4 and Ar, the volumetric flow ratio of CF4 to other components of the second process gas being from about 1:0 to about 1:10.

Abstract: A fluorine-free integrated process for plasma etching aluminum lines in an integrated circuit structure including an overlying anti-reflection coating (ARC) and a dielectric layer underlying the aluminum, the process being preferably performed in a single plasma reactor. The ARC open uses either BCl3/Cl2 or Cl2 and possibly a hydrocarbon passivating gas, preferably C2H4. The aluminum main etch preferably includes BCl3/Cl2 etch and C2H4 diluted with He. The dilution is particularly effective for small flow rates of C2H4. An over etch into the Ti/TiN barrier layer and part way into the underlying dielectric may use a chemistry similar to the main etch. A Cl2/O2 chamber cleaning may be performed, preferably with the wafer removed from the chamber and after every wafer cycle.

Abstract: A process for etching a substrate 25 in an etching chamber 30, and simultaneously cleaning a thin, non-homogeneous, etch residue deposited on the surfaces of the walls 45 and components of the etching chamber 30. In the etching step, process gas comprising etchant gas is used to etch a substrate 25 in the etching chamber 30 thereby depositing etch residue inside the chamber 30. Cleaning gas is added to the process gas for a sufficient time and in a volumetric flow ratio that is sufficiently high, to react with and remove substantially all the etch residue deposited by the process gas. The present method advantageously cleans the etch residue in the chamber 30, during the etching process, and without use of separate cleaning, conditioning, and seasoning process steps.

Abstract: One embodiment of the present invention is a process for etching an organic anti-reflective coating on a base of a substrate, the process including steps of: (a) placing the substrate into a processing chamber; (b) introducing into the processing chamber a processing gas including one or more of carbon monoxide (CO), carbon dioxide (CO2), and sulfur oxide (SO2); and (c) forming a plasma from the processing gas to etch the organic anti-reflective coating layer.

Abstract: One embodiment of the present invention is a process for etching an organic anti-reflective coating on a base of a substrate, the process including steps of: (a) placing the substrate into a processing chamber; (b) introducing into the processing chamber a processing gas including one or more of carbon monoxide (CO), carbon dioxide (CO2), and sulfur oxide (SO2); and (c) forming a plasma from the processing gas to etch the organic anti-reflective coating layer.

Abstract: Method and apparatus for cleaning ceramic surfaces of parts used, for example, and without limitation, in semiconductor processing equipment. In particular, one embodiment of the present invention is a method for cleaning a ceramic part that includes steps of: (a) treating the surface using one or more first mechanical processes; (b) treating the surface using one or more chemical processes; (c) plasma conditioning the surface; and (d) treating the surface using one or more second mechanical processes.

Abstract: A process for etching a substrate and removing etch residue deposited on the surfaces in the etching chamber has two stages. In the first stage, an energized first process gas is provided in the chamber, and in the second stage, an energized second process gas is provided in the chamber. The energized first process gas comprises SF6 and Ar, the volumetric flow ratio of SF6 to other components of the first process gas being from about 5:1 to about 1:10. The energized second process gas comprises CF4 and Ar, the volumetric flow ratio of CF4 to other components of the second process gas being from about 1:0 to about 1:10.