Abstract: A semiconductor device includes: a cell gate trench with a bottom face and first/second side faces; a field-shield gate trench narrower than the cell gate trench; a first upper diffusion layer between the cell gate trench and the field-shield gate trench; a second upper diffusion layer on the opposite side of the cell gate trench from the first upper diffusion layer; a third upper diffusion layer on the opposite side of the field-shield gate trench from the first upper diffusion layer; a lower diffusion layer on the bottom face of the cell gate trench; first and second storage elements electrically connected to the first and second upper diffusion layers, respectively; a bit line electrically connected to the lower diffusion layer; a word line covering first and second side faces via a gate insulating film; and a field-shield gate electrode in the field-shield gate trench via a gate insulating film.

Abstract: In a TFT that adopts an oxide semiconductor as an active layer and has a resistance layer interposed between the active layer and one of a source and drain electrode, while Vth close to 0 V and a small off current are sustained, an on-current is increased. In a thin-film transistor including a gate electrode, a gate insulating film, a semiconductor layer, a source electrode, and a drain electrode, the semiconductor layer that links the source electrode and drain electrode is made of a metal oxide. The semiconductor layer includes three regions of first, second, and third regions. The first region is connected with the source electrode, the third region is connected with the drain electrode, and the second region is connected between the first region and third region. The resistivities of the three regions have the relationship of the first region>the second region>the third region.

Abstract: In a manufacturing method for thin film transistors, the following procedure is taken: a sacrifice layer comprised of a metal oxide semiconductor is formed over a conductive layer comprised of a metal oxide semiconductor; a metal film is formed over the sacrifice layer; the metal film is processed by dry etching; and the portion of the sacrifice layer exposed by this dry etching is subjected to wet etching.

Abstract: A phenomenon of change of a contact resistance between an oxide semiconductor and a metal depending on an oxygen content ratio in introduced gas upon depositing an oxide semiconductor film made of indium gallium zinc oxide, zinc tin oxide, or others in an oxide semiconductor thin-film transistor. A contact layer is formed with an oxygen content ratio of 10% or higher in a region from a surface, where the metal and the oxide semiconductor are contacted, down to at least 3 nm deep in depth direction, and a region to be a main channel layer is further formed with an oxygen content ratio of 10% or lower, so that a multilayered structure is formed, and both of ohmic characteristics to the electrode metal and reliability such as the suppression of threshold potential shift are achieved.

Abstract: A method for manufacturing a thin film transistor (TFT) through a process including back exposure, in which oxide semiconductor is used for a channel layer; using an electrode over a substrate as a mask, negative resist is exposed to light from the back of the substrate; the negative resist except its exposed part is removed; and an electrode is shaped by etching a conductive film using the exposed part as an etching mask.

Abstract: Features are forming a gate electrode on an insulating substrate; forming a first semiconducting layer mainly composed of an indium oxide and having a film thickness of 5 nm or more onto the gate electrode interposing a gate insulating film; forming a second semiconducting layer mainly composed of zinc and tin oxides without containing indium and having a film thickness of 5 to 50 nm on the first semiconducting layer, and including a step of forming a source electrode and a drain electrode on the second semiconducting layer. In this manner, by combining the materials of the first semiconducting layer and the second semiconducting layer with each other, a semiconductor device with a reduced dependency on the film thickness of the semiconducting layer, little characteristic variations on a large area substrate is provided.

Abstract: Disclosed herein is a device that includes a semiconductor substrate having a first area, a plurality of cell transistors arranged on the first area of the semiconductor substrate, and a plurality of cell capacitors each coupled to an associated one of the cell transistors, the cell capacitors being provided so as to overlap with one another on the first area.

Abstract: A semiconductor device including: a bit line being arranged on top surfaces of first and second contact plugs via a first insulation layer and extending in a direction connecting a first impurity diffusion layer and a second impurity diffusion layer; a bit line contact plug being formed through the first insulation layer and electrically connecting the bit line to the first contact plug; a first cell capacitor having a first lower electrode beside one of side surfaces of the bit line; a first insulation film insulating the bit line and the first lower electrode from each other; and a first contact conductor electrically connecting a bottom end of the first lower electrode to a side surface of the second contact plug.

Abstract: A semiconductor IC includes grooves formed in a substrate to define a first dummy region and second dummy regions formed at a scribing area, and third dummy regions and a fourth dummy region formed at a product area. A width of the first dummy region is greater than widths of each of the second and third dummy regions and a width of the fourth dummy region is greater than widths of each of the third dummy regions. A conductor pattern is formed over the first dummy region for optical pattern recognition. The first dummy region is formed under the conductor pattern so the grooves are not formed under the conductor pattern. The second dummy regions are spaced from one another by a predetermined spacing at the scribing area, and the third dummy regions are spaced from one another by a predetermined spacing at the product area.

Abstract: A semiconductor device includes a plurality of MOS transistors and wiring connected to a source electrode or a drain electrode of the plurality of MOS transistors and, the wiring being provided in the same layer as the source electrode and the drain electrode in a substrate, or in a position deeper than a surface of the substrate.

Abstract: A semiconductor IC includes grooves formed in a substrate to define a first dummy region and second dummy regions formed at a scribing area, and third dummy regions and a fourth dummy region formed at a product area. A width of the first dummy region is greater than widths of each of the second and third dummy regions and a width of the fourth dummy region is greater than widths of each of the third dummy regions. A conductor pattern is formed over the first dummy region for optical pattern recognition. The first dummy region is formed under the conductor pattern so the grooves are not formed under the conductor pattern. The second dummy regions are spaced from one another by a predetermined spacing at the scribing area, and the third dummy regions are spaced from one another by a predetermined spacing at the product area.

Abstract: A semiconductor device includes a plurality of MOS transistors and wiring connected to a source electrode or a drain electrode of the plurality of MOS transistors and, the wiring being provided in the same layer as the source electrode and the drain electrode in a substrate, or in a position deeper than a surface of the substrate.

Abstract: A semiconductor IC includes grooves formed in a substrate to define a first dummy region and second dummy regions formed at a scribing area, and third dummy regions and a fourth dummy region formed at a product area. A width of the first dummy region is greater than widths of each of the second and third dummy regions and a width of the fourth dummy region is greater than widths of each of the third dummy regions. A conductor pattern is formed over the first dummy region for optical pattern recognition. The first dummy region is formed under the conductor pattern so the grooves are not formed under the conductor pattern. The second dummy regions are spaced from one another by a predetermined spacing at the scribing area, and the third dummy regions are spaced from one another by a predetermined spacing at the product area.

Abstract: A technique capable of forming an oxide semiconductor target with a high quality in a low cost is provided. In a step of manufacturing zinc tin oxide (ZTO target) used in manufacturing an oxide semiconductor forming a channel layer of a thin-film transistor, by purposely adding the group IV element (C, Si, or Ge) or the group V element (N, P, or As) to a raw material, excessive carriers caused by the group III element (Al) mixed in the step of manufacturing the ZTO target are suppressed, and a thin-film transistor having good current (Id)-voltage (Vg) characteristics is achieved.

Abstract: A semiconductor device includes: a cell gate trench with a bottom face and first/second side faces; a field-shield gate trench narrower than the cell gate trench; a first upper diffusion layer between the cell gate trench and the field-shield gate trench; a second upper diffusion layer on the opposite side of the cell gate trench from the first upper diffusion layer; a third upper diffusion layer on the opposite side of the field-shield gate trench from the first upper diffusion layer; a lower diffusion layer on the bottom face of the cell gate trench; first and second storage elements electrically connected to the first and second upper diffusion layers, respectively; a bit line electrically connected to the lower diffusion layer; a word line covering first and second side faces via a gate insulating film; and a field-shield gate electrode in the field-shield gate trench via a gate insulating film.

Abstract: A self emission silicon emission display is provided at a low price, which contains silicon and oxygen which exist in abundance on the earth as the main component and which can be easily formed by conventional silicon process. A light emission element includes a first electrode for injecting electrons, a second electrode for injecting holes, and a light emission part electrically connected to the first electrode and the second electrode, where the light emission part includes amorphous or polycrystalline silicon consisting of a single layer or plural layers and where the dimension of the silicon in at least one direction is controlled to be several nanometers.

Abstract: A semiconductor device includes: a transistor including source and drain diffusion-layers, a gate insulating film and a gate electrode; first and second plugs formed in a first interlayer-insulating film and connected to the source and drain diffusion-layers, respectively; a third plug extending through a second interlayer-insulating film and connected to the first plug; a first interconnection-wire formed on the second interlayer-insulating film and connected to the third plug; a second interconnection-wire formed on a third interlayer-insulating film and intersecting the first interconnection-wire; a fourth interlayer-insulating film; a hole extending through the fourth, third and second interlayer-insulating films, the hole being formed such that a side surface of the second interconnection-wire is exposed; and a fourth plug filling the hole via an intervening dielectric film and connected to the second plug, wherein a capacitor is formed using the fourth plug, the second interconnection-wire and the diele

Abstract: A semiconductor device comprises MOS transistors sequentially arranged in the plane direction of a substrate, wherein a gate electrode and a wiring portion for connecting between the gate electrodes to each other are implanted into a layer that is lower than a surface of the substrate in which a diffusion layer has been formed. A first device isolation area with a STI structure for separating the diffusion layers that function as a source/drain area is formed on the surface of the substrate. A second device isolation area with the STI structure for separating channel areas of the MOS transistors adjacent to each other is formed in a layer that is lower than a layer that has the first device isolation area.

Abstract: A metallic oxide semiconductor device with high performance and small variations. It is a field effect transistor using a metallic oxide film for the channel, which includes a channel region and a source region and comprises a drain region with a lower oxygen content than the channel region in the metallic oxide, in which the channel region exhibits semiconductor characteristics and the oxygen content decreases with depth below the surface.

Abstract: A method of manufacturing a field effect transistor, which has high alignment accuracy between a gate electrode and source and drain electrodes and can provide a transparent device at a low cost. Since a patterned light blocking film is formed on the rear side of a substrate and used as a photomask for forming a gate electrode pattern and a source and drain electrode pattern on the front side of the substrate, the number of photomasks is reduced, and self-alignment between the gate electrode and the source and drain electrodes is carried out, thereby improving the alignment accuracy of these electrodes. Thereby, a method of manufacturing a high-accuracy low-cost field effect transistor can be provided.