Abstract: To provide a semiconductor device provided with an element isolation structure capable of hindering an adverse effect on electric characteristics of a semiconductor element, and a method of manufacturing the same. The thickness of a first silicon oxide film left in a shallow trench isolation having a relatively narrow width is thinner than the first silicon oxide film left in a shallow trench isolation having a relatively wide width. A second silicon oxide film (an upper layer) having a relatively high compressive stress by an HDP-CVD method is more thickly laminated over the first silicon oxide film in a lower layer by a thinned thickness of the first silicon oxide film. The compressive stress of an element isolation oxide film finally formed in a shallow trench isolation having a relatively narrow width is more enhanced.

Abstract: To provide a semiconductor device provided with an element isolation structure capable of hindering an adverse effect on electric characteristics of a semiconductor element, and a method of manufacturing the same. The thickness of a first silicon oxide film left in a shallow trench isolation having a relatively narrow width is thinner than the first silicon oxide film left in a shallow trench isolation having a relatively wide width. A second silicon oxide film (an upper layer) having a relatively high compressive stress by an HDP-CVD method is more thickly laminated over the first silicon oxide film in a lower layer by a thinned thickness of the first silicon oxide film. The compressive stress of an element isolation oxide film finally formed in a shallow trench isolation having a relatively narrow width is more enhanced.

Abstract: To provide a semiconductor device provided with an element isolation structure capable of hindering an adverse effect on electric characteristics of a semiconductor element, and a method of manufacturing the same. The thickness of a first silicon oxide film left in a shallow trench isolation having a relatively narrow width is thinner than the first silicon oxide film left in a shallow trench isolation having a relatively wide width. A second silicon oxide film (an upper layer) having a relatively high compressive stress by an HDP-CVD method is more thickly laminated over the first silicon oxide film in a lower layer by a thinned thickness of the first silicon oxide film. The compressive stress of an element isolation oxide film finally formed in a shallow trench isolation having a relatively narrow width is more enhanced.

Abstract: In order to block hydrogen ions produced when forming an interlayer insulating film by HDP-CVD or the like to thereby suppress an adverse effect of the hydrogen ions on a device, in a semiconductor device including a contact layer, a metal interconnection and an interlayer insulating film on a semiconductor substrate having a gate electrode formed thereon, the interlayer insulating film is formed on the metal interconnection by bias-applied plasma CVD using source gas containing hydrogen atoms, and a silicon oxynitride film is provided in the underlayer of the metal interconnection and the interlayer insulating film.

Abstract: In order to block hydrogen ions produced when forming an interlayer insulating film by HDP-CVD or the like to thereby suppress an adverse effect of the hydrogen ions on a device, in a semiconductor device including a contact layer, a metal interconnection and an interlayer insulating film on a semiconductor substrate having a gate electrode formed thereon, the interlayer insulating film is formed on the metal interconnection by bias-applied plasma CVD using source gas containing hydrogen atoms, and a silicon oxynitride film is provided in the underlayer of the metal interconnection and the interlayer insulating film.

Abstract: In order to block hydrogen ions produced when forming an interlayer insulating film by HDP-CVD or the like to thereby suppress an adverse effect of the hydrogen ions on a device, in a semiconductor device including a contact layer, a metal interconnection and an interlayer insulating film on a semiconductor substrate having a gate electrode formed thereon, the interlayer insulating film is formed on the metal interconnection by bias-applied plasma CVD using source gas containing hydrogen atoms, and a silicon oxynitride film is provided in the underlayer of the metal interconnection and the interlayer insulating film.

Abstract: To provide a semiconductor device provided with an element isolation structure capable of hindering an adverse effect on electric characteristics of a semiconductor element, and a method of manufacturing the same. The thickness of a first silicon oxide film left in a shallow trench isolation having a relatively narrow width is thinner than the first silicon oxide film left in a shallow trench isolation having a relatively wide width. A second silicon oxide film (an upper layer) having a relatively high compressive stress by an HDP-CVD method is more thickly laminated over the first silicon oxide film in a lower layer by a thinned thickness of the first silicon oxide film. The compressive stress of an element isolation oxide film finally formed in a shallow trench isolation having a relatively narrow width is more enhanced.

Abstract: An interconnection is provided with a dummy interconnection connected to an interconnection body, and the dummy interconnection is provided with a stress concentration portion in which tensile stress higher than that of the interconnection body is generated. In proximity to the stress concentration portion, an insulating film formed by high-density plasma CVD is provided, and the tensile stress is generated in the stress concentration portion by the insulating film. With this structure, the occurrence of a void can be prevented at any position in the interconnection body.

Abstract: In order to block hydrogen ions produced when forming an interlayer insulating film by HDP-CVD or the like to thereby suppress an adverse effect of the hydrogen ions on a device, in a semiconductor device including a contact layer, a metal interconnection and an interlayer insulating film on a semiconductor substrate having a gate electrode formed thereon, the interlayer insulating film is formed on the metal interconnection by bias-applied plasma CVD using source gas containing hydrogen atoms, and a silicon oxynitride film is provided in the underlayer of the metal interconnection and the interlayer insulating film.

Abstract: An interconnection is provided with a dummy interconnection connected to an interconnection body, and the dummy interconnection is provided with a stress concentration portion in which tensile stress higher than that of the interconnection body is generated. In proximity to the stress concentration portion, an insulating film formed by high-density plasma CVD is provided, and the tensile stress is generated in the stress concentration portion by the insulating film. With this structure, the occurrence of a void can be prevented at any position in the interconnection body.

Abstract: The present invention aims at offering the filled structure of an oxide film etc. which can form an insulating film (oxide film) without void in a predetermined depressed portion by an economical and practical method and without increasing RF bias. According to the first invention, the oxide film filled structure is provided with the foundation (silicon substrate) having a depressed portion (trench), and the oxide film (silicon oxide film) formed in the depressed portion concerned. Here, the oxide film concerned includes the silicon oxide film region of silicon-richness in part at least.

Abstract: An interconnection is provided with a dummy interconnection connected to an interconnection body, and the dummy interconnection is provided with a stress concentration portion in which tensile stress higher than that of the interconnection body is generated. In proximity to the stress concentration portion, an insulating film formed by high-density plasma CVD is provided, and the tensile stress is generated in the stress concentration portion by the insulating film. With this structure, the occurrence of a void can be prevented at any position in the interconnection body.

Abstract: In order to block hydrogen ions produced when forming an interlayer insulating film by HDP-CVD or the like to thereby suppress an adverse effect of the hydrogen ions on a device, in a semiconductor device including a contact layer, a metal interconnection and an interlayer insulating film on a semiconductor substrate having a gate electrode formed thereon, the interlayer insulating film is formed on the metal interconnection by bias-applied plasma CVD using source gas containing hydrogen atoms, and a silicon oxynitride film is provided in the underlayer of the metal interconnection and the interlayer insulating film.

Abstract: A plurality of metal wire layers consisting of a first metal wire layer and a second metal wire layer are formed on a semiconductor substrate. A fluorinated silicate glass film serving as an interlayer metal dielectric film is formed between the first and second metal wire layers. A silicon nitride film serving as a protective insulation film is formed on the fluorinated silicate glass film layer. An adhesive layer made of, for example, a P-SiO film, P-SiON film, or PE-SiO film, is formed between the fluorinated silicate glass film and the silicon nitride film.

Abstract: A plurality of metal wire layers consisting of a first metal wire layer and a second metal wire layer are formed on a semiconductor substrate. A fluorinated silicate glass film serving as an interlayer metal dielectric film is formed between the first and second metal wire layers. A silicon nitride film serving as a protective insulation film is formed on the fluorinated silicate glass film layer. An adhesive layer made of, for example, a P—SiO film, P—SiON film, or PE-SiO film, is formed between the fluorinated silicate glass film and the silicon nitride film.

Abstract: An interconnection is provided with a dummy interconnection connected to an interconnection body, and the dummy interconnection is provided with a stress concentration portion in which tensile stress higher than that of the interconnection body is generated. In proximity to the stress concentration portion, an insulating film formed by high-density plasma CVD is provided, and the tensile stress is generated in the stress concentration portion by the insulating film. With this structure, the occurrence of a void can be prevented at any position in the interconnection body.

Abstract: An interconnection is formed on a semiconductor substrate having a semiconductor element formed thereon. Next, a passivation film is formed on the semiconductor substrate including the interconnection. Further, a polyimide film, which is served as a buffer coating film, is formed on the passivation film. Further, the polyimide film is patterned. Next, the passivation film is subject to etching while the patterned polyimide film is taken as a mask. Next, a hardened layer, which is formed on the surface of the polyimide film as a result of etching, is removed through ashing process. Next, the semiconductor substrate after ashing process is cured so as to transform the polyimide film into imide.

Abstract: It is possible to obtain a semiconductor device with an element isolation structure showing a good isolation characteristic by filing an interior of a minute trench with a good quality insulating film free of a defect such as a void, and a manufacturing method therefor. The semiconductor device includes a semiconductor substrate and an isolation insulator. A trench is formed on a main surface of the semiconductor substrate. The isolation insulator is formed in an interior of the trench using a thermal oxidation method to isolate element forming regions from each other on the main surface of the semiconductor substrate. The isolation insulator is a lamination body formed by a plurality of oxide film layers.

Abstract: A plurality of metal wire layers consisting of a first metal wire layer and a second metal wire layer are formed on a semiconductor substrate. A fluorinated silicate glass film serving as an interlayer metal dielectric film is formed between the first and second metal wire layers. A silicon nitride film serving as a protective insulation film is formed on the fluorinated silicate glass film layer. An adhesive layer made of, for example, a P—SiO film, P—SiON film, or PE-SiO film, is formed between the fluorinated silicate glass film and the silicon nitride film.

Abstract: A manufacturing method of a semiconductor device allowing successful filling of an insulating film by HDP-CVD (High Density Plasma-Chemical Vapor Deposition) in a gap or valley between densely placed interconnections is provided. The method includes the steps of forming semiconductor elements on a semiconductor substrate, forming on the semiconductor elements a plurality of interconnections with top protective layers side by side to electrically connect the semiconductor elements, forming a protective insulating film by CVD other than HDP-CVD to cover top and side surfaces of the interconnections and a bottom surface of a gap between the interconnections, and forming an insulating film by HDP-CVD to cover the protective insulating film and to fill in the gap between the interconnections covered with the protective insulating film.