Abstract: Method of manufacturing a semiconductor device having a buried wiring structure comprising copper in which a conductive barrier film 17a of buried second layer wirings L2 is protected against oxidation upon forming an insulative film 15b for wiring cap with an SiON film formed by a plasma CVD method using a gas mixture, for example, of a trimethoxysilane gas and a nitrogen oxidized gas, whereby dielectric break down strength between wirings comprising copper as the main conductor layer of the semiconductor device can be improved.

Abstract: Over a plug, a stopper insulating film made of an organic film is formed, followed by successive formation of an insulating film and a hard mask. In the presence of a patterned resist film, the hard mask is dry etched, whereby an interconnection groove pattern is transferred thereto. By ashing with oxygen plasma, the resist film is removed to form the interconnection-groove-pattern-transferred hard mask. At this time, the organic film constituting the stopper insulating film has been covered with the insulating film. Then, the insulating film, stopper insulating film and hard mask are removed to form the groove pattern of interconnection. Hydrogen annealing may be conducted after formation of the plug, or the stopper insulating film may be formed over the plug via an adhesion layer.

Abstract: In order to provide an anticorrosive technique for metal wirings formed by a chemical mechanical polishing (CMP) method, a process for manufacturing a semiconductor integrated circuit device according to the invention comprises the steps of: forming a metal layer of Cu (or a Cu alloy containing Cu as a main component) over the major face of a wafer and then planarizing the metal layer by a chemical mechanical polishing (CMP) method to form metal wirings; anticorroding the planarized major face of the wafer to form a hydrophobic protective film over the surfaces of the metal wirings; immersing the anticorroded major face of the wafer or keeping the same in a wet state so that it may not become dry; and post-cleaning the major face, kept in the wet state, of the wafer.

Abstract: After formation of Cu interconnections 46a to 46e each to be embedded in an interconnection groove 40 of a silicon oxide film 39 by CMP and then washing, the surface of each of the silicon oxide film 39 and Cu interconnections 46a to 46e is treated with a reducing plasma (ammonia plasma). Then, without vacuum break, a cap film (silicon nitride film) is formed continuously. This process makes it possible to improve the dielectric breakdown resistance (reliability) of a copper interconnection formed by the damascene method.

Abstract: Provided is a fabrication method of a semiconductor integrated circuit device having a post-CMP cleaning apparatus equipped with at least two drying chambers downstream of a cleaning chamber. This makes it possible to dry wafers in parallel, thereby improving the through-put of the post-CMP cleaning.

Abstract: After formation of Cu interconnections 46a to 46e each to be embedded in an interconnection groove 40 of a silicon oxide film 39 by CMP and then washing, the surface of each of the silicon oxide film 39 and Cu interconnections 46a to 46e is treated with a reducing plasma (ammonia plasma). Then, without vacuum break, a cap film (silicon nitride film) is formed continuously. This process makes it possible to improve the dielectric breakdown resistance (reliability) of a copper interconnection formed by the damascene method.

Abstract: After formation of Cu interconnections 46a to 46e each to be embedded in an interconnection groove 40 of a silicon oxide film 39 by CMP and then washing, the surface of each of the silicon oxide film 39 and Cu interconnections 46a to 46e is treated with a reducing plasma (ammonia plasma). Then, without vacuum break, a cap film (silicon nitride film) is formed continuously. This process makes it possible to improve the dielectric breakdown resistance (reliability) of a copper interconnection formed by the damascene method.

Abstract: After formation of Cu interconnections 46a to 46e each to be embedded in an interconnection groove 40 of a silicon oxide film 39 by CMP and then washing, the surface of each of the silicon oxide film 39 and Cu interconnections 46a to 46e is treated with a reducing plasma (ammonia plasma). Then, without vacuum break, a cap film (silicon nitride film) is formed continuously. This process makes it possible to improve the dielectric breakdown resistance (reliability) of a copper interconnection formed by the damascene method.

Abstract: In a semiconductor integrated circuit wherein an interlayer insulating film is formed over a semiconductor substrate having a semiconductor device formed thereover; and an interconnection embedded in an interconnection groove in the interlayer insulating film is formed by the deposition of a metal film such as copper and polishing by the CMP method, another interlayer insulating film over the interconnection and interlayer insulating film is formed to have a blocking film, a planarizing film and an insulating film. As the planarizing film, a film having fluidity such as SOG is employed.

Abstract: After formation of Cu interconnections 46a to 46e each to be embedded in an interconnection groove 40 of a silicon oxide film 39 by CMP and then washing, the surface of each of the silicon oxide film 39 and Cu interconnections 46a to 46e is treated with a reducing plasma (ammonia plasma). Then, without vacuum break, a cap film (silicon nitride film) is formed continuously. This process makes it possible to improve the dielectric breakdown resistance (reliability) of a copper interconnection formed by the damascene method.

Abstract: In order to provide an anticorrosive technique for metal wirings formed by a chemical mechanical polishing (CMP) method, a process for manufacturing a semiconductor integrated circuit device according to the invention comprises the steps of: forming a metal layer of Cu (or a Cu alloy containing Cu as a main component) over the major face of a wafer and then planarizing the metal layer by a chemical mechanical polishing (CMP) method to form metal wirings; anticorroding the planarized major face of the wafer to form a hydrophobic protective film over the surfaces of the metal wirings; immersing the anticorroded major face of the wafer or keeping the same in a wet state so that it may not become dry; and post-cleaning the major face, kept in the wet state, of the wafer.

Abstract: Over a plug, a stopper insulating film made of an organic film is formed, followed by successive formation of an insulating film and a hard mask. In the presence of a patterned resist film, the hard mask is dry etched, whereby an interconnection groove pattern is transferred thereto. By ashing with oxygen plasma, the resist film is removed to form the interconnection-groove-pattern-transferred hard mask. At this time, the organic film constituting the stopper insulating film has been covered with the insulating film. Then, the insulating film, stopper insulating film and hard mask are removed to form the groove pattern of interconnection. Hydrogen annealing may be conducted after formation of the plug, or the stopper insulating film may be formed over the plug via an adhesion layer.

Abstract: After formation of Cu interconnections 46a to 46e each to be embedded in an interconnection groove 40 of a silicon oxide film 39 by CMP and then washing, the surface of each of the silicon oxide film 39 and Cu interconnections 46a to 46e is treated with a reducing plasma (ammonia plasma). Then, without vacuum break, a cap film (silicon nitride film) is formed continuously. This process makes it possible to improve the dielectric breakdown resistance (reliability) of a copper interconnection formed by the damascene method.

Abstract: In order to provide an anticorrosive technique for metal wirings formed by a chemical mechanical polishing (CMP) method, a process for manufacturing a semiconductor integrated circuit device according to the invention comprises the steps of: forming a metal layer of Cu (or a Cu alloy containing Cu as a main component) over the major face of a wafer and then planarizing the metal layer by a chemical mechanical polishing (CMP) method to form metal wirings; anticorroding the planarized major face of the wafer to form a hydrophobic protective film over the resurfaces of the metal wirings; immersing the anticorroded major face of the wafer or keeping the same in a wet state so that it may not become dry; and post-cleaning the major face, kept in the wet state, of the wafer.

Abstract: After formation of Cu interconnections 46a to 46e each to be embedded in an interconnection groove 40 of a silicon oxide film 39 by CMP and then washing, the surface of each of the silicon oxide film 39 and Cu interconnections 46a to 46e is treated with a reducing plasma (ammonia plasma). Then, without vacuum break, a cap film (silicon nitride film) is formed continuously. This process makes it possible to improve the dielectric breakdown resistance (reliability) of a copper interconnection formed by the damascene method.

Abstract: After formation of Cu interconnections 46a to 46e each to be embedded in an interconnection groove 40 of a silicon oxide film 39 by CMP and then washing, the surface of each of the silicon oxide film 39 and Cu interconnections 46a to 46e is treated with a reducing plasma (ammonia plasma). Then, without vacuum break, a cap film (silicon nitride film) is formed continuously. This process makes it possible to improve the dielectric breakdown resistance (reliability) of a copper interconnection formed by the damascene method.

Abstract: After formation of Cu interconnections 46a to 46e each to be embedded in an interconnection groove 40 of a silicon oxide film 39 by CMP and then washing, the surface of each of the silicon oxide film 39 and Cu interconnections 46a to 46e is treated with a reducing plasma (ammonia plasma). Then, without vacuum break, a cap film (silicon nitride film) is formed continuously. This process makes it possible to improve the dielectric breakdown resistance (reliability) of a copper interconnection formed by the damascene method.

Abstract: A semiconductor device comprises a semiconductor substrate; a first insulating film overlying a surface of the semiconductor substrate, an upper surface of the first insulating film being nitrided; a first copper-embedded interconnection embedded in the first insulating film, and which first copper-embedded interconnection contains copper as a main component; a copper nitride film overlying an upper surface of the first copper-embedded interconnection; a cap insulating film overlying an upper surface of the first insulating film and an upper surface of the copper nitride film; and a second insulting film overlying the cap insulating film.

Abstract: In a semiconductor integrated circuit wherein an interlayer insulating film is formed over a semiconductor substrate having a semiconductor device formed thereover; and an interconnection embedded in an interconnection groove in the interlayer insulating film is formed by the deposition of a metal film such as copper and polishing by the CMP method, another interlayer insulating film over the interconnection and interlayer insulating film is formed to have a blocking film, a planarizing film and an insulating film. As the planarizing film, a film having fluidity such as SOG is employed.

Abstract: In order to provide an anticorrosive technique for metal wirings formed by a chemical mechanical polishing (CMP) method, a process for manufacturing a semiconductor integrated circuit device according to the invention comprises the steps of: forming a metal layer of Cu (or a Cu alloy containing Cu as a main component) over the major face of a wafer and then planarizing the metal layer by a chemical mechanical polishing (CMP) method to form metal wirings; anticorroding the planarized major face of the wafer to form a hydrophobic protective film over the surfaces of the metal wirings; immersing the anticorroded major face of the wafer or keeping the same in a wet state so that it may not become dry; and post-cleaning the major face, kept in the wet state, of the wafer.