Abstract: A static random access memory fabrication method includes forming a gate stack on a substrate, forming isolating spacers adjacent the gate stack, the isolating spacers and gate stack having a gate length, forming a source and drain region adjacent the gate stack, which generates an effective gate length, wherein the source and drain regions are formed from a low extension dose implant that varies a difference between the gate length and the effective gate length.

Abstract: Asymmetric FET devices and methods for fabrication thereof that employ a variable pitch gate are provided. In one aspect, a method for fabricating a FET device includes the following steps. A wafer is provided. A plurality of active areas is formed in the wafer using STI. A plurality of gate stacks is formed on the wafer, wherein the gate stacks have an irregular gate-to-gate spacing such that for at least a given one of the active areas a gate-to-gate spacing on a source side of the given active area is greater than a gate-to-gate spacing on a drain side of the given active area. Spacers are formed on opposite sides of the gate stacks. An angled implant is performed into the source side of the given active area. A FET device is also provided.

Abstract: A ZnO-based semiconductor device includes an n type ZnO-based semiconductor layer, an aluminum oxide film formed on the n type ZnO-based semiconductor layer, and a palladium layer formed on the aluminum oxide film. With this configuration, the n type ZnO-based semiconductor layer and the palladium layer form a Schottky barrier structure.

Abstract: A semiconductor device 100 includes: a first silicon carbide layer 120 arranged on the principal surface of a semiconductor substrate 101; a first impurity region 103 of a first conductivity type arranged in the first silicon carbide layer; a body region 104 of a second conductivity type; a contact region 131 of the second conductivity type which is arranged at a position in the body region that is deeper than the first impurity region 103 and which contains an impurity of the second conductivity type at a higher concentration than the body region; a drift region 102 of the first conductivity type; and a first ohmic electrode 122 in ohmic contact with the first impurity region 103 and the contact region 131, wherein: a contact trench 121, which penetrates through the first impurity region 103, is provided in the first silicon carbide layer 120; and the first ohmic electrode 122 is arranged in the contact trench 121 and is in contact with the contact region 131 on at least a portion of a side wall lower portio

Abstract: A nitride-based semiconductor device according to the present disclosure includes a nitride-based semiconductor multilayer structure 20 with a p-type semiconductor region, of which the surface 12 defines a tilt angle of one to five degrees with respect to an m plane, and an electrode 30, which is arranged on the p-type semiconductor region. The p-type semiconductor region is made of an AlxInyGazN (where x+y+z=1, x?0, y?0 and z?0) semiconductor layer 26. The electrode 30 includes an Mg layer 32, which is in contact with the surface 12 of the p-type semiconductor region, and a metal layer 34 formed on the Mg layer 32. The metal layer 34 is formed from at least one metallic element that is selected from the group consisting of Pt, Mo and Pd.

Abstract: A semiconductor element according to the present invention can perform both a transistor operation and a diode operation via its channel layer. If the potential Vgs of its gate electrode 165 with respect to that of its source electrode 150 is 0 volts, then a depletion layer with a thickness Dc, which has been depleted entirely in the thickness direction, is formed in at least a part of the channel layer 150 due to the presence of a pn junction between a portion of its body region 130 and the channel layer 150, and another depletion layer that has a thickness Db as measured from the junction surface of the pn junction is formed in that portion of the body region 130.

Abstract: A silicon carbide layer is epitaxially formed on a main surface of a substrate. The silicon carbide layer is provided with a trench having a side wall inclined relative to the main surface. The side wall has an off angle of not less than 50° and not more than 65° relative to a {0001} plane. A gate insulating film is provided on the side wall of the silicon carbide layer. The silicon carbide layer includes: a body region having a first conductivity type and facing a gate electrode with the gate insulating film being interposed therebetween; and a pair of regions separated from each other by the body region and having a second conductivity type. The body region has an impurity density of 5×1016 cm?3 or greater. This allows for an increased degree of freedom in setting a threshold voltage while suppressing decrease of channel mobility.

Abstract: A circuit board that can decrease thermal stress acting between a semiconductor element and a board in association with temperature alteration and has high mechanical strength (rigidity) as a whole board (including a multilayer wiring layer) is provided. Ceramic base material having a coefficient of thermal expansion close to that of a semiconductor element and inner layer wiring are integrally sintered, and the circuit board is configured so that fine-lined conductor structure corresponding to a multilayer wiring layer in the inner layer wiring has predetermined width, intralayer interval and interlayer interval. Thereby, thermal stress acting between a semiconductor element and the board when the board is exposed to temperature alteration in a condition where it is joined with the semiconductor element is suppressed, rigidity of the board is maintained, and its reliability against temperature cycle is increased.

Abstract: A first semiconductor layer extends from the element region to the element-termination region, and functions as a drain of the MOS transistor. A second semiconductor layer extends, below the first semiconductor layer, from the element region to the element-termination region. A third semiconductor layer extends from the element region to the element-termination region, and is in contact with the second semiconductor layer to function as a drift layer of the MOS transistor. A distance between a boundary between the first semiconductor layer and the field oxide film, and the end portion of the third semiconductor layer on the fifth semiconductor layer side in the element region is smaller than that between a boundary between the first semiconductor layer and the field oxide layer and an end portion of the third semiconductor layer on the fifth semiconductor layer side in the element-termination region.