Abstract: There is provided a non-volatile semiconductor memory device exhibiting excellent electrical characteristics and a method of fabricating the same. The semiconductor device includes a semiconductor substrate having two trenches, an isolation oxide film provided in the trench, a floating gate electrode, an ONO film, and a control gate electrode. The isolation oxide film has an upper surface with a region having a curvature protruding downward. The floating gate electrode has a flat upper surface and extends from a main surface of the semiconductor substrate between the two trenches to the two isolation oxide films. The ONO film extends from the upper surface of the floating gate electrode to a side surface of the floating gate electrode. The control gate electrode is provided on the ONO film to extend from the upper surface of the floating gate electrode to the side surface of the floating gate electrode.

Abstract: The present fabrication method includes the steps of: providing a nitride film in a main surface of a semiconductor substrate; providing an upper trench, with the nitride film used as a mask; filling the upper trench with an oxide film introduced therein; removing the oxide film to expose at least a portion of a bottom of the upper trench and allowing a remainder of the oxide film to serve as a sidewall; providing a lower trench in a bottom of the upper trench, with the sidewall used as a mask; and with the upper trench having the sidewall remaining therein, providing an oxide film in the upper trench and the lower trench. This can provide a semiconductor device fabrication method and a semiconductor device preventing a contact from penetrating the device in an interconnection process.

Abstract: The present fabrication method includes the steps of: providing a nitride film in a main surface of a semiconductor substrate; providing an upper trench, with the nitride film used as a mask; filling the upper trench with an oxide film introduced therein; removing the oxide film to expose at least a portion of a bottom of the upper trench and allowing a remainder of the oxide film to serve as a sidewall; providing a lower trench in a bottom of the upper trench, with the sidewall used as a mask; and with the upper trench having the sidewall remaining therein, providing an oxide film in the upper trench and the lower trench. This can provide a semiconductor device fabrication method and a semiconductor device preventing a contact from penetrating the device in an interconnection process.

Abstract: There is provided a non-volatile semiconductor memory device exhibiting excellent electrical characteristics and a method of fabricating the same. The semiconductor device includes a semiconductor substrate having two trenches, an isolation oxide film provided in the trench, a floating gate electrode, an ONO film, and a control gate electrode. The isolation oxide film has an upper surface with a region having a curvature protruding downward. The floating gate electrode has a flat upper surface and extends from a main surface of the semiconductor substrate between the two trenches to the two isolation oxide films. The ONO film extends from the upper surface of the floating gate electrode to a side surface of the floating gate electrode. The control gate electrode is provided on the ONO film to extend from the upper surface of the floating gate electrode to the side surface of the floating gate electrode.

Abstract: The present fabrication method includes the steps of: providing a nitride film in a main surface of a semiconductor substrate; providing an upper trench, with the nitride film used as a mask; filling the upper trench with an oxide film introduced therein; removing the oxide film to expose at least a portion of a bottom of the upper trench and allowing a remainder of the oxide film to serve as a sidewall; providing a lower trench in a bottom of the upper trench, with the sidewall used as a mask; and with the upper trench having the sidewall remaining therein, providing an oxide film in the upper trench and the lower trench. This can provide a semiconductor device fabrication method and a semiconductor device preventing a contact from penetrating the device in an interconnection process.

Abstract: The invention provides a semiconductor device having a multilayer wiring structure in which a plurality of layers are provided on a substrate and in which a connection wiring is formed on each layer, wherein a dummy pattern almost as high as the connection wiring is provided in a predetermined region of each layer so that an outer peripheral portion of the dummy pattern is adjacent to the connection wiring, the dummy pattern is formed linearly at least on the outer peripheral portion, and a distance between a linearly formed portion and a portion inside of the linearly formed portion is set to be equal to or narrower than a distance between the connection wiring and the linearly formed portion.

Abstract: The invention provides a semiconductor device having a multilayer wiring structure in which a plurality of layers are provided on a substrate and in which a connection wiring is formed on each layer, wherein a dummy pattern almost as high as the connection wiring is provided in a predetermined region of each layer so that an outer peripheral portion of the dummy pattern is adjacent to the connection wiring, the dummy pattern is formed linearly at least on the outer peripheral portion, and a distance between a linearly formed portion and a portion inside of the linearly formed portion is set to be equal to or narrower than a distance between the connection wiring and the linearly formed portion.

Abstract: A field oxide film which is fine and having smaller upheaval of a bird's head is formed, so as to improve electrical characteristic of a conductive layer formed with end portions positioned on the field oxide film. A planarizing silicon film is formed on a silicon nitride film and a thermal oxide film, so as to planarize a concave generated between the thermal oxide film and a silicon nitride film. The planarizing silicon film is thermally oxidized, so as to form a planarizing thermal oxide film integrated with the thermal oxide film. Thereafter, the planarizing thermal oxide film is etched back to form the field oxide film, and the silicon nitride film and a polycrystalline silicon film are removed. Thereafter, the conductive layer with end portions positioned on the field oxide film is formed.