Abstract: A non-volatile semiconductor memory device includes a memory cell transistor having a memory cell capable of writing and erasing data, and a peripheral circuit that drives the memory cell which includes a first p-channel MOS transistor including a gate electrode that is formed on a semiconductor layer with a first gate insulation film therebetween, a channel region that is formed on a surface of the semiconductor layer and has a first peak dopant concentration, a source region and a drain region that have a second peak dopant concentration higher than the first peak dopant concentration, and overlap regions that extend between the channel region and the source region and the drain region, and also below a portion of the gate electrode, that have a third peak dopant concentration higher than the first peak dopant concentration and lower than the second peak dopant concentration by one order of magnitude or more.

Abstract: A semiconductor memory device comprises a memory block including conductive layers at different levels from a substrate and separated from each other by a first insulation material. A memory pillar extends through the first conductive layers. A hookup region is adjacent to the memory block and includes conductive layers stacked on the substrate at levels from the substrate that corresponds to the conductive layers in the memory block. An isolation region is between the memory block and the hookup region and includes first insulating layers of a second insulating material different than the first insulating material. Each first insulating layer is at a level from the substrate that corresponds to one of the first conductive layers and each first insulating layer is between one of the conductive layers in the memory block and one of the conductive layers in hookup region.

Abstract: A semiconductor memory device comprises a memory block including conductive layers at different levels from a substrate and separated from each other by a first insulation material. A memory pillar extends through the first conductive layers. A hookup region is adjacent to the memory block and includes conductive layers stacked on the substrate at levels from the substrate that corresponds to the conductive layers in the memory block. An isolation region is between the memory block and the hookup region and includes first insulating layers of a second insulating material different than the first insulating material. Each first insulating layer is at a level from the substrate that corresponds to one of the first conductive layers and each first insulating layer is between one of the conductive layers in the memory block and one of the conductive layers in hookup region.

Abstract: After forming a first film over the main surface of a semiconductor substrate, the first film is patterned, thereby forming a control gate electrode for a non-volatile memory, a dummy gate electrode, and a first film pattern. Subsequently, a memory gate electrode for the non-volatile memory adjacent to the control gate electrode is formed. Then, the first film pattern is patterned thereby forming a gate electrode and a dummy gate electrode.

Abstract: According to one embodiment, a nonvolatile semiconductor storage device includes a word line transfer unit which transfers voltage applied to a memory cell selected on the basis of an address to a word line. The word line transfer unit includes a word line transfer transistor which is arranged in a first layout area of the word line transfer unit and transfers voltage applied to the memory cell to the word line and a dummy word line transfer transistor which is arranged in a second layout area provided outside an end of the first layout area and does not transfer voltage applied to the memory cell to the word line.

Abstract: After forming a first film over the main surface of a semiconductor substrate, the first film is patterned, thereby forming a control gate electrode for a non-volatile memory, a dummy gate electrode, and a first film pattern. Subsequently, a memory gate electrode for the non-volatile memory adjacent to the control gate electrode is formed. Then, the first film pattern is patterned thereby forming a gate electrode and a dummy gate electrode.

Abstract: A semiconductor device includes MOS transistors, capacitor elements, a voltage generating circuit, a contact plug, and a memory cell. The MOS transistor and the capacitor element are formed on a first one of the element regions and a second one of the element regions, respectively. In the voltage generating circuit, current paths of the MOS transistors are series-connected and the capacitor elements are connected to the source or drain of the MOS transistors. The contact plug is formed on the source or the drain to connect the MOS transistors or one of the MOS transistors and one of the capacitor elements. A distance between the gate and the contact plug both for a first one of the MOS transistors located in the final stage in the series connection is larger than that for a second one of the MOS transistors located in the initial stage in the series connection.

Abstract: After forming a first film over the main surface of a semiconductor substrate, the first film is patterned, thereby forming a control gate electrode for a non-volatile memory, a dummy gate electrode, and a first film pattern. Subsequently, a memory gate electrode for the non-volatile memory adjacent to the control gate electrode is formed. Then, the first film pattern is patterned thereby forming a gate electrode and a dummy gate electrode.

Abstract: A non-volatile semiconductor memory device includes a memory cell configured to allow electrical writing and erasing, a bit line configured to transmit a potential corresponding to data stored in the memory cell in a column direction, a sense amplifier circuit configured to detect a potential of the bit line, and a bit line coupling circuit coupled between the bit line and the sense amplifier circuit. The bit line coupling circuit includes a first bit line coupling transistor in an outer layout area of the bit line coupling circuit and a second bit line coupling transistor in an inner layout area of the bit line coupling circuit. The first bit line coupling transistor has a longer distance in a channel length direction or in a channel width direction between an impurity diffused layer coupled to the bit line and an element isolation area than the second bit line coupling transistor.

Abstract: A non-volatile semiconductor memory device includes a memory cell transistor having a memory cell capable of writing and erasing data, and a peripheral circuit that drives the memory cell which includes a first p-channel MOS transistor including a gate electrode that is formed on a semiconductor layer with a first gate insulation film therebetween, a channel region that is formed on a surface of the semiconductor layer and has a first peak dopant concentration, a source region and a drain region that have a second peak dopant concentration higher than the first peak dopant concentration, and overlap regions that extend between the channel region and the source region and the drain region, and also below a portion of the gate electrode, that have a third peak dopant concentration higher than the first peak dopant concentration and lower than the second peak dopant concentration by one order of magnitude or more.

Abstract: A semiconductor device according to an embodiment includes a gate wire including a laminated film in which a polysilicon film, a barrier conductive film, and a metal film are laminated in this order; a first contact plug/upper layer wire arranged above the source or the drain; a second upper layer wire arranged above an element isolation region; a second contact plug arranged apart from the second upper layer wire and connecting the metal film and the polysilicon film above a channel region; and a third contact plug formed apart from the polysilicon film in the element isolation region and connecting the second upper layer wire and the metal film. The second contact plug includes a barrier metal in contact with the polysilicon film and the barrier conductive film is made of WN, TaN, or Ta and the barrier metal is made of Ti or TiN.

Abstract: According to one embodiment, a nonvolatile semiconductor storage device includes a word line transfer unit which transfers voltage applied to a memory cell selected on the basis of an address to a word line. The word line transfer unit includes a word line transfer transistor which is arranged in a first layout area of the word line transfer unit and transfers voltage applied to the memory cell to the word line and a dummy word line transfer transistor which is arranged in a second layout area provided outside an end of the first layout area and does not transfer voltage applied to the memory cell to the word line.

Abstract: According to one embodiment, a semiconductor memory includes a memory cell in a memory cell array which is provided in a semiconductor substrate and which includes a first active region surrounded by a first isolation insulator, a transistor in a transistor region which is provided in the semiconductor substrate and which includes second active regions surrounded by a second isolation insulator. The second isolation insulator includes a first film, and a second film between the first film and the second active region, and the upper surface of the first film is located closer to the bottom of the semiconductor substrate than the upper surface of the second film.

Abstract: A semiconductor device according to an embodiment includes a gate wire including a laminated film in which a polysilicon film, a barrier conductive film, and a metal film are laminated in this order; a first contact plug/upper layer wire arranged above the source or the drain; a second upper layer wire arranged above an element isolation region; a second contact plug arranged apart from the second upper layer wire and connecting the metal film and the polysilicon film above a channel region; and a third contact plug formed apart from the polysilicon film in the element isolation region and connecting the second upper layer wire and the metal film. The second contact plug includes a barrier metal in contact with the polysilicon film and the barrier conductive film is made of WN, TaN, or Ta and the barrier metal is made of Ti or TiN.

Abstract: A semiconductor device includes MOS transistors, capacitor elements, a voltage generating circuit, a contact plug, and a memory cell. The MOS transistor and the capacitor element are formed on a first one of the element regions and a second one of the element regions, respectively. In the voltage generating circuit, current paths of the MOS transistors are series-connected and the capacitor elements are connected to the source or drain of the MOS transistors. The contact plug is formed on the source or the drain to connect the MOS transistors or one of the MOS transistors and one of the capacitor elements. A distance between the gate and the contact plug both for a first one of the MOS transistors located in the final stage in the series connection is larger than that for a second one of the MOS transistors located in the initial stage in the series connection.

Abstract: A semiconductor memory device includes a source region, a drain region, a channel region, a charge storage layer, and a control gate electrode. The source region and drain region are formed separately from each other in a surface of a semiconductor substrate. The channel region is formed in the semiconductor substrate and located between the source region and the drain region. The charge storage layer is formed on the channel region with a first insulating film interposed therebetween. The control gate electrode is formed on the charge storage layer with a second insulating film interposed therebetween. The control gate has an upper corner portion rounded with a radius of curvature of 5 nm or more.

Abstract: A method of manufacturing a semiconductor device involves process for forming gate insulating films of different thickness on a semiconductor substrate, depositing films that constitute a gate electrode, removing the gate insulating films having different thickness formed on an impurity diffusion region surface of a transistor including the gate electrode, and doping impurities into a portion where the gate insulating film is removed.

Abstract: A non-volatile semiconductor storage device includes: a memory cell array having memory cells arranged therein, the memory cells storing data in a non-volatile manner; and a plurality of transfer transistors transferring a voltage to the memory cells, the voltage to be supplied for data read, write and erase operations with respect to the memory cells. Each of the transfer transistors includes: a gate electrode formed on a semiconductor substrate via a gate insulation film; and diffusion layers formed to sandwich the gate electrode therebetween and functioning as drain/source layers. Upper layer wirings are provided above the diffusion layers and provided with a predetermined voltage to prevent depletion of the diffusion layers at least when the transfer transistors become conductive.

Abstract: A non-volatile semiconductor storage device includes: a memory cell array having memory cells arranged therein, the memory cells storing data in a non-volatile manner; and a plurality of transfer transistors transferring a voltage to the memory cells, the voltage to be supplied for data read, write and erase operations with respect to the memory cells. Each of the transfer transistors includes: a gate electrode formed on a semiconductor substrate via a gate insulation film; and diffusion layers formed to sandwich the gate electrode therebetween and functioning as drain/source layers. Upper layer wirings are provided above the diffusion layers and provided with a predetermined voltage to prevent depletion of the diffusion layers at least when the transfer transistors become conductive.

Abstract: A non-volatile semiconductor storage device includes: a memory cell array having memory cells arranged therein, the memory cells storing data in a non-volatile manner; and a plurality of transfer transistors transferring a voltage to the memory cells, the voltage to be supplied for data read, write and erase operations with respect to the memory cells. Each of the transfer transistors includes: a gate electrode formed on a semiconductor substrate via a gate insulation film; and diffusion layers formed to sandwich the gate electrode therebetween and functioning as drain/source layers. Upper layer wirings are provided above the diffusion layers and provided with a predetermined voltage to prevent depletion of the diffusion layers at least when the transfer transistors become conductive.