Abstract: A field effect transistor (FET) includes a first semiconductor layer and a second semiconductor layer, the second semiconductor layer being formed on the first semiconductor layer and having a band gap energy greater than that of the first semiconductor layer. The first and second semiconductor layers are made of a Group III-V compound semiconductor layer, formed on the first semiconductor layer are a gate electrode 36 and a source electrode 35, formed on the second semiconductor layer is a drain electrode 37, and the drain electrode and the gate electrode are formed respectively on opposing planes of a semiconductor structure which contains the first and second semiconductor layers. This arrangement enables a drain's breakdown voltage to be increased in the FET, because the gate electrode 36 and the drain electrode 37 are respectively disposed, in a spatial separation of each other, on different planes instead of the same plane of the semiconductor structure.

Abstract: Integrated circuit components are described that are formed using selective epitaxy such that the integrated circuit components, such as transistors, are vertically oriented. These structures have regions that are doped in situ during selective epitaxial growth of the component body. These components are grown directly in electrical communication lines. Moreover, these components are adapted for use in memory devices and are believed to not require the use of shallow trench isolation.

Abstract: A heterojunction device includes a first layer of p-type aluminum gallium nitride; a second layer of undoped gallium nitride on the first layer; a third layer of aluminum gallium nitride on the second layer; and an electron gas between the second and third layers. A heterojunction between the first and second layers injects positive charge into the second layer to compensate and/or neutralize negative charge within the electron gas.

Abstract: A nitride semiconductor device according to one embodiment of the present invention includes: a non-doped first aluminum gallium nitride (AlxGa1-xN (0?x?1)) layer which is formed as a channel layer; a non-doped or n type second aluminum gallium nitride (AlyGa1-yN (0?y?1, x <y)) layer which is formed on the first aluminum gallium nitride layer as a barrier layer; an aluminum nitride (AlN) film which is formed on the second aluminum gallium nitride layer as a gate insulating film lower layer; an aluminum oxide (AL2O3) film which is formed on the aluminum nitride film as a gate insulating film upper layer; a source electrode and a drain electrode which are formed as first and second main electrodes to be electrically connected to the second aluminum gallium nitride layer, respectively; and a gate electrode which is formed on the aluminum oxide film as a control electrode.

Abstract: One-transistor ferroelectric memory devices using an indium oxide film (In2O3), an In2O3 film structure, and corresponding fabrication methods have been provided. The method for controlling resistivity in an In2O3 film comprises: depositing an In film using a PVD process, typically with a power in the range of 200 to 300 watts; forming a film including In overlying a substrate material; simultaneously (with the formation of the In-including film) heating the substrate material, typically the substrate is heated to a temperature in the range of 20 to 200 degrees C.; following the formation of the In-including film, post-annealing, typically in an O2 atmosphere; and, in response to the post-annealing: forming an In2O3 film; and, controlling the resistivity in the In2O3 film. For example, the resistivity can be controlled in the range of 260 to 800 ohm-cm.

Abstract: A semiconductor device of the invention includes a first conductive type semiconductor base substrate; and a switching mechanism which is formed on a first main surface of the semiconductor base substrate and switches ON/OFF of a current. In the semiconductor base substrate, a plurality of columnar hetero-semiconductor regions are formed at spaced intervals within the semiconductor substrate, and the hetero-semiconductor regions are made of a semiconductor material having a different band gap from the semiconductor substrate and extend between the first main surface and a second main surface opposite to the first main surface.