Abstract: A semiconductor device of a selective gate region having a semiconductor layer, a first insulating film formed on the semiconductor layer, a first electrode layer formed on the first insulating film, and an element isolating region including an element isolating insulating film formed to extend through the first electrode layer and the first insulating film to reach an inner region of the semiconductor layer. The element isolating region isolates an element region and is self-aligned with the first electrode layer, a second insulating film is formed on the first electrode layer and the element isolating region, and an open portion exposes a surface of the first electrode layer and is formed in the second insulating film. A second electrode layer is formed on the second insulating film and the exposed surface of the first electrode layer, the second electrode layer being electrically connected to the first electrode layer via the open portion.

Abstract: A semiconductor device is disclosed, which comprises trench type device isolation regions formed in a semiconductor substrate, semiconductor active regions electrically isolated by the isolation regions, a first electrode layer formed to self-align to the isolation regions, and a second electrode layer formed over the first electrode layer with an insulating film interposed therebetween, the top of each of the isolation regions being located, in an area where the second electrode layer is present, at a first level below the top of the first electrode layer and above the surface of the active regions and, in an area where the second electrode layer is not present, at a second level below the first level, and the surface of the active regions being at substantially the same level in the area where the second electrode layer is present and in the area where the second electrode layer is not present.

Abstract: A semiconductor device is disclosed, which comprises trench type device isolation regions formed in a semiconductor substrate, semiconductor active regions electrically isolated by the isolation regions, a first electrode layer formed to self-align to the isolation regions, and a second electrode layer formed over the first electrode layer with an insulating film interposed therebetween, the top of each of the isolation regions being located, in an area where the second electrode layer is present, at a first level below the top of the first electrode layer and above the surface of the active regions and, in an area where the second electrode layer is not present, at a second level below the first level, and the surface of the active regions being at substantially the same level in the area where the second electrode layer is present and in the area where the second electrode layer is not present.

Abstract: A first side-wall film is formed on the sides of a gate electrode of a high-voltage transistor, and a second side-wall film is provided on the first side-wall film. The first side-wall film has an etching rate lower that of a pre-metal dielectric, and the second side-wall film has an etching rate substantially equal to that of the of the pre-metal dielectric. The LDD of the high-voltage transistor is provided in that part of the semiconductor substrate which lies right below the first and second side-wall films. The source/drain diffusion layer of the high-voltage transistor is formed in that part of the substrate which is outside the second side-wall film. A first side-wall film having an etching rate lower than that of the pre-metal dielectric and/or a second side-wall film having an etching rate substantially equal to that of the pre-metal dielectric are provided on the sides of the gate electrode of the low voltage transistor.

Abstract: A semiconductor device at least has a memory cell array. The memory cell array has active regions extending linearly in parallel with one another at predetermined intervals and each containing alternating source and drain regions, gate electrodes orthogonally crossing the active regions between the source and drain regions and each having a floating gate and a control gate laid one upon another, first conductors extending linearly in parallel with the gate electrodes and connected to corresponding ones of the source regions through source contacts, and second conductors connected to corresponding ones of the drain regions through drain contacts.

Abstract: A nonvolatile semiconductor memory which is configured to include a plurality of word lines disposed in a row direction; a plurality of bit lines disposed in a column direction perpendicular to the word lines; memory cell transistors having a charge storage layer, provided in the column direction and an electronic storage condition of the memory cell transistor configured to be controlled by one of the plurality of the word lines connected to the memory cell; a plurality of first select transistors, each including a gate electrode, selecting the memory cell transistors provided in the column direction, arranged in the column direction and adjacent to the memory cell transistors at a first end of the memory cell transistors; and a first select gate line connected to each of the gate electrodes of the first select transistors.

Abstract: A semiconductor device of a selective gate region having a semiconductor layer, a first insulating film formed on the semiconductor layer, a first electrode layer formed on the first insulating film, and an element isolating region including an element isolating insulating film formed to extend through the first electrode layer and the first insulating film to reach an inner region of the semiconductor layer. The element isolating region isolates an element region and is self-aligned with the first electrode layer, a second insulating film is formed on the first electrode layer and the element isolating region, and an open portion exposes a surface of the first electrode layer and is formed in the second insulating film. A second electrode layer is formed on the second insulating film and the exposed surface of the first electrode layer, the second electrode layer being electrically connected to the first electrode layer via the open portion.

Abstract: A method of manufacturing a semiconductor memory integrated circuit intended to improve properties and reliability of its peripheral circuit includes the step of forming a tunnel oxide film (21a) in the cell array region, gate oxide film (21b) for a high-voltage circuit and gate oxide film (21c) for a low-voltage circuit both in the peripheral circuit to respectively optimum values of thickness, and covering them with a first-layer polycrystalline silicon film (22). After that, device isolation grooves (13) are formed and buried with a device isolation insulating film (14). The first-layer polycrystalline silicon film (24) is a non-doped film, and after device isolation, a second-layer polycrystalline silicon film (24) is doped with phosphorus in the cell array region to form floating gates made of the first-layer polycrystalline silicon film (22) and the second-layer polycrystalline silicon film (24).

Abstract: A non-volatile semiconductor memory device according to the present invention has a semiconductor substrate and a memory cell having a floating gate provided through a tunnel insulating layer on the semiconductor substrate, and a control gate provided through an inter-layer insulting layer on said floating gate. The inter-insulating layer includes a silicon oxide layer contiguous to said floating gate, a first silicon nitride layer provided by a CVD method on the silicon oxide layer and a second silicon nitride layer provided on said first silicon nitride layer and having a lower trap density than that of the first silicon nitride layer. The inter-insulating layer may includes a silicon oxide layer contiguous to said floating gate and a silicon oxide layer deposited on said silicon oxide layer and having a quantity of hydrogen content on the order of 1019/cm3 or less.

Abstract: A nonvolatile semiconductor memory device including at least one MOS transistor in a peripheral circuit comprises a semiconductor substrate, isolation insulating films for defining a plurality of element formation regions, each of the isolation insulating films being buried in an isolation trench provided in the semiconductor substrate, a floating gate provided in each of the element formation regions via a first gate insulating film, a control gate provided on the floating gate via a second gate insulating film, and source and drain regions provided in the semiconductor substrate in self-alignment with the control gate, wherein the floating gate is self-aligned at an isolation end in a direction of a channel width, and comprises a plurality of polysilicon films.

Abstract: A nonvolatile semiconductor memory which is configured to include a plurality of word lines disposed in a row direction; a plurality of bit lines disposed in a column direction perpendicular to the word lines; memory cell transistors having a charge storage layer, provided in the column direction and an electronic storage condition of the memory cell transistor configured to be controlled by one of the plurality of the word lines connected to the memory cell; a plurality of first select transistors, each including a gate electrode, selecting the memory cell transistors provided in the column direction, arranged in the column direction and adjacent to the memory cell transistors at a first end of the memory cell transistors; and a first select gate line connected to each of the gate electrodes of the first select transistors.

Abstract: A semiconductor device of a selective gate region having a semiconductor layer, a first insulating film formed on the semiconductor layer, a first electrode layer formed on the first insulating layer, and an element isolating region including an element isolating insulating film formed to extend through the first electrode layer and the first insulating film to reach an inner region of the semiconductor layer. The element isolating region isolates an element region and is self-aligned with the first electrode layer, a second insulating film is formed on the first electrode layer and the element isolating region, and an open portion exposes a surface of the first electrode layer and is formed in the second insulating film. A second electrode layer is formed on the second insulating film and the exposed surface of the first electrode layer, the second electrode layer being electrically connected to the first electrode layer via the open portion.

Abstract: A first insulation film, a first conductor film, and a cap are sequentially formed on a semiconductor substrate. The first insulation film, the first conductor film, and the cap, and the substrate are etched in the same pattern. A second insulation film is placed in that etched pattern. The cap is removed. A second conductor film is formed on the side face of the second insulation film.

Abstract: A first insulation film, a first conductor film, and a cap are sequentially formed on a semiconductor substrate. The first insulation film, the first conductor film, and the cap, and the substrate are etched in the same pattern. A second insulation film is placed in that etched pattern. The cap is removed. A second conductor film is formed on the side face of the second insulation film.

Abstract: A first insulation film, a first conductor film, and a cap are sequentially formed on a semiconductor substrate. The first insulation film, the first conductor film, and the cap, and the substrate are etched in the same pattern. A second insulation film is placed in that etched pattern. The cap is removed. A second conductor film is formed on the side face of the second insulation film.

Abstract: A plurality of nonvolatile memory elements formed on element regions respectively isolated by element isolation regions on a main surface of a first conductive type semiconductor substrate, the nonvolatile semiconductor memory elements comprising a gate insulating film formed on the main surface of the semiconductor substrate, a plurality of floating electrodes formed along a first direction on the gate insulating film, a plurality of grooves formed among the plurality of floating electrodes, groove insulating films filled in the plurality of the grooves, a second conductive type impurity diffusion region formed along a second direction so as to sandwich the floating electrodes, interelectrode insulating films formed along the first direction on the plurality of floating electrodes and the groove insulating films, and control electrodes formed on the interelectrode insulating films.

Abstract: Forming of a first silicon oxide film is started on an internal surface of a trench formed on a surface or upwardly of a semiconductor substrate according to an HDP technique. Then, deposition of the first silicon oxide film stops before an opening of the trench closes. Further, the first silicon oxide film deposited in the vicinity of an opening is etched, and a second silicon oxide film is formed on the first silicon oxide film deposited on the bottom of the trench according to the HDP technique. In this manner, the first and second silicon oxide films can be laminated on the bottom of the trench.

Abstract: A method of manufacturing a semiconductor memory integrated circuit intended to improve properties and reliability of its peripheral circuit includes the step of forming a tunnel oxide film (21a) in the cell array region, gate oxide film (21b) for a high-voltage circuit and gate oxide film (21c) for a low-voltage circuit both in the peripheral circuit to respectively optimum values of thickness, and covering them with a first-layer polycrystalline silicon film (22). After that, device isolation grooves (13) are formed and buried with a device isolation insulating film (14). The first-layer polycrystalline silicon film (24) is a non-doped film, and after device isolation, a second-layer polycrystalline silicon film (24) is doped with phosphorus in the cell array region to form floating gates made of the first-layer polycrystalline silicon film (22) and the second-layer polycrystalline silicon film (24).

Abstract: Forming of a first silicon oxide film is started on an internal surface of a trench formed on a surface or upwardly of a semiconductor substrate according to an HDP technique. Then, deposition of the first silicon oxide film stops before an opening of the trench closes. Further, the first silicon oxide film deposited in the vicinity of an opening is etched, and a second silicon oxide film is formed on the first silicon oxide film deposited on the bottom of the trench according to the HDP technique. In this manner, the first and second silicon oxide films can be laminated on the bottom of the trench.

Abstract: A nonvolatile semiconductor memory which is configured to include a plurality of word lines disposed in a row direction; a plurality of bit lines disposed in a column direction perpendicular to the word lines; memory cell transistors having a charge storage layer, provided in the column direction and an electronic storage condition of the memory cell transistor configured to be controlled by one of the plurality of the word lines connected to the memory cell; a plurality of first select transistors, each including a gate electrode, selecting the memory cell transistors provided in the column direction, arranged in the column direction and adjacent to the memory cell transistors at a first end of the memory cell transistors; and a first select gate line connected to each of the gate electrodes of the first select transistors.