Abstract: A capacitor consisting of a storage electrode (19), a capacitor dielectric film (20) and a plate electrode (21) is formed in a trench formed through dielectric films (6, 8, 10 and 12) stacked on a semiconductor substrate (1) and buried wiring layers (9 and 11) are formed under the capacitor. As the capacitor is formed not in the semiconductor substrate but over it, there is room in area in which the capacitor can be formed and the difficulty of forming wiring is reduced by using the wiring layers (9 and 11) for a global word line and a selector line.

Abstract: A capacitor consisting of a storage electrode (19), a capacitor dielectric film (20) and a plate electrode (21) is formed in a trench formed through dielectric films (6, 8, 10 and 12) stacked on a semiconductor substrate (1) and buried wiring layers (9 and 11) are formed under the capacitor. As the capacitor is formed not in the semiconductor substrate but over it, there is room in area in which the capacitor can be formed and the difficulty of forming wiring is reduced by using the wiring layers (9 and 11) for a global word line and a selector line.

Abstract: A low threshold voltage NMIS area and a high threshold voltage PMIS area are set by a photoresist mask also used for well formation. Using a photoresist mask with openings for the NMIS and PMIS, the NMIS and PMIS areas are set by one ion implantation step. After gate oxidation, ion implantation is conducted through an amorphous silicon film onto wells, channels, and gate electrodes. A plurality of CMIS threshold voltages can be set and the gate electrodes of both polarities can be formed in a reduced number of steps using photoresist. This solves the problem in which photomasks are required as many as there are ion implantation types for wells, channel stoppers, gate electrodes, and threshold voltage control and hence the number of manufacturing steps and the production cost are increased.

Abstract: Since a memory cell of a so-called MRAM utilizing a conventional tunnel magnetic resistance forms writing word lines below data lines, there are the following problems. A process becomes hard because it is necessary to execute a self-aligned contact opening process with passing through portions between the writing word lines, or since it is hard that the writing word lines sufficiently overlap with a magnetic resistance device in a planner manner due to a restriction of layout, the data writing becomes unstable. In order to solve the problems mentioned above, the present invention provides a structure of MRAM memory cell in which the writing word lines are formed above the bit lines, and a method of manufacturing the same.

Abstract: According to the present invention, an overlay margin is secured for matching a wiring electrode 11 with a storage electrode 15 of a capacitor at their point of contact and the required area for a memory cell can be decreased by placing the plug electrode 11 of titanium nitride in the active region of a semiconductor substrate or over the gate electrode, reducing the size of the opening for passing the storage electrode 15 of the capacitor of a stacked structure, and decreasing the line width of a wiring electrode 13. By the common use of the above-mentioned plug electrodes in a CMISFET region in the peripheral circuit and in a memory cell of a static RAM, their circuit layouts can be made compact.

Abstract: A semiconductor memory device and a method of fabricating the same are provided, in which an interlayer film which only covers a peripheral circuit region except a memory cell array is formed above the peripheral circuit region to reduce a topological difference between both regions after bitlines are formed; therefore, a semiconductor substrate which has a plain surface as a main one can be used as a starting body with no preliminary processing thereon and a shallow trench isolation technique can also be applied. Besides, interconnects to the peripheral circuit can be led up to the surface of the device through a multi-step plug connection and thereby processing of large aspect-ratio holes, the filling up of the holes with metal and the like are unnecessary and, as a result, reliability of the process is improved.

Abstract: According to the present invention, an overlay margin is secured for matching a wiring electrode 11 with a storage electrode 15 of a capacitor at their point of contact and the required area for a memory cell can be decreased by placing the plug electrode 11 of titanium nitride in the active region of a semiconductor substrate or over the gate electrode, reducing the size of the opening for passing the storage electrode 15 of the capacitor of a stacked structure, and decreasing the line width of a wiring electrode 13. By the common use of the above-mentioned plug electrodes in a CMISFET region in the peripheral circuit and in a memory cell of a static RAM, their circuit layouts can be made compact.

Abstract: According to the present invention, an overlay margin is secured for matching a wiring electrode 11 with a storage electrode 15 of a capacitor at their point of contact and the required area for a memory cell can be decreased by placing the plug electrode 11 of titanium nitride in the active region of a semiconductor substrate or over the gate electrode, reducing the size of the opening for passing the storage electrode 15 of the capacitor of a stacked structure, and decreasing the line width of a wiring electrode 13. By the common use of the above-mentioned plug electrodes in a CMISFET region in the peripheral circuit and in a memory cell of a static RAM, their circuit layouts can be made compact.

Abstract: A semiconductor integrated circuit device offering a phase pattern makeup that excludes mixture of insular and linear patterns in a mask for forming a single wire electrode layer so as to eliminate inconsistency in the Levenson arrangement of phase shifters. A plurality of wire electrodes are spaced a minimum size apart and are in different phases. Between two adjacent wire electrodes are plug electrodes each formed with an upper and a lower layer plug electrode in direct contact, with no intervention of wire electrodes and without the presence of an insular pattern made of the same wire electrode layer. This setup allows the Levenson arrangement to take shape for enhanced pattern density, whereby a semiconductor integrated circuit device of a high degree of integration is implemented.

Abstract: A semiconductor memory device and a method of fabricating the same are provided, in which an interlayer film which only covers a peripheral circuit region except a memory cell array region is formed above the peripheral circuit region to reduce a topological difference between both regions after bitlines are formed, therefore a semiconductor substrate which has a plain surface as a main one can be used as a starting body with no preliminary processing thereon and a shallow trench isolation technique can also be applied, besides interconnects to the peripheral circuit can be led up to the surface of the device through a multi-step plug connection and thereby processing of large aspect-ratio holes, stuffing of metal in the holes and the like are unnecessary and as a result reliability of the process is improved.

Abstract: A very thin oxide film is formed at an opening formed in an insulator film and a conductor layer, on a substrate, and impurity-containing polysilicon is formed on the sidewall of the opening. Impurity diffusion from the from the silicon into the substrate through the very thin oxide film causes a lowering in effective concentration of the diffused impurities, resulting in the formation of shallower source/drain region. Thereafter, a gate insulator film and a gate electrode are formed on the substrate surface in an area bounded by an insulator film formed on the sidewall of the opening. The gate electrode smaller than the opening, the size of which corresponds to the limit of processing, and the shallower source/drain region afford a miniaturized MOSFET.

Abstract: A semiconductor field effect transistor is provided which permits controlling of the phase of carriers between a source region and a drain region formed in a first semiconductor layer. Such control can be used to modulate characteristics such as the electric conductivity and drain current of the transistor. To accomplish this control, a gate electrode is formed over a portion of said first semiconductor layer between the source and drain regions. The gate electrode splits to form first and second branches at a first location adjacent to the source region. These first and second branches subsequently rejoin one another at a second location adjacent to said drain region. When a potential is applied to the gate electrode, it will produce first and second two-dimensional carriers conduction paths at a surface of the portion of the first semiconductor layer under the first and second branches.

Abstract: A process for producing ceramic products such as turbine rotors comprises the steps of contouring a prefired ceramic roughly or primarily formed workpiece into a desired shape by means of a rod-shaped cutting tool having a working end or tip to which abrasive particles have been secured, said tool being rotated about its axis; subjecting the contoured surface of said workpiece to an abrasive finishing; and thereafter firing said workpiece thus finished.