A high-frequency conductor having improved conductivity comprises at least one electrically conductive base material. The ratio of the outer and inner surfaces of the base material permeable by a current to the total volume of the base material is increased by a) dividing the base material perpendicularly to the direction of current into at least two segments, which are spaced from each other by an electrically conductive intermediate piece and connected both electrically and mechanically to each other, and/or b) topographical structures in or on the surface of the base material and/or c) inner porosity of at least a portion of the base material compared to a design of the base material in which the respective feature was omitted. It was found that, as a result of these measures concerning the design, it is possible to physically arrange the same amount abase material so that a larger fraction of the base material is located at a distance of no more than skin depth from an outer or inner surface and is thus involved in current transport. As a result, a lesser fraction remains unused as a function of the skin effect.

A high-frequency conductor having improved conductivity comprises at least one electrically conductive base material. The ratio of the outer and inner surfaces of the base material permeable by a current to the total volume of the base material is increased by a) dividing the base material perpendicularly to the direction of current into at least two segments, which are spaced from each other by an electrically conductive intermediate piece and connected both electrically and mechanically to each other, and/or b) topographical structures in or on the surface of the base material and/or c) inner porosity of at least a portion of the base material compared to a design of the base material in which the respective feature was omitted. It was found that, as a result of these measures concerning the design, it is possible to physically arrange the same amount abase material so that a larger fraction of the base material is located at a distance of no more than skin depth from an outer or inner surface and is thus involved in current transport. As a result, a lesser fraction remains unused as a function of the skin effect.

Disclosed is a power device, such as power MOSFET, and method for fabricating same. The device includes an upper trench situated over a lower trench, where the upper trench is wider than the lower trench. The device further includes a trench dielectric inside the lower trench and on sidewalls of the upper trench. The device also includes an electrode situated within the trench dielectric. The trench dielectric of the device has a bottom thickness that is greater than a sidewall thickness.

A semiconductor device having electrodes of three or more levels, includes: a semiconductor substrate; an epitaxial layer formed on the semiconductor substrate; a transistor formed on the epitaxial layer; a source electrode formed on the epitaxial layer and electrically connected to a source of the transistor; and a gate drawing electrode formed on the epitaxial layer and electrically connected to a gate of the transistor, wherein the source electrode includes a first source electrode, a second source electrode which is an electrode at a second or higher level on the first source electrode, and a third source electrode which is an electrode at a third or higher level on the second source electrode and above the gate drawing electrode, and the gate drawing electrode is an electrode at a second or higher level on the first source electrode and surrounded with the first, second, and third source electrodes.

A semiconductor device having electrodes of three or more levels, includes: a semiconductor substrate; an epitaxial layer formed on the semiconductor substrate; a transistor formed on the epitaxial layer; a source electrode formed on the epitaxial layer and electrically connected to a source of the transistor; and a gate drawing electrode formed on the epitaxial layer and electrically connected to a gate of the transistor, wherein the source electrode includes a first source electrode, a second source electrode which is an electrode at a second or higher level on the first source electrode, and a third source electrode which is an electrode at a third or higher level on the second source electrode and above the gate drawing electrode, and the gate drawing electrode is an electrode at a second or higher level on the first source electrode and surrounded with the first, second, and third source electrodes.

A method for preparing film patterns; firstly, a complementary film pattern (1) to a desired film pattern (201) is prepared on a substrate (3) with an erasable agent; secondly, a whole layer of film (2) is formed on the complementary film pattern (1); and thirdly, the desired film pattern (201) is obtained by removing the complementary film pattern (1). The preparation method can simplify the production process and reduce the production cost of the film patterns.

A semiconductor device having favorable electrical characteristics is provided. The semiconductor device is manufactured by a first step of forming a semiconductor layer containing a metal oxide, a second step of forming a first insulating layer, a third step of forming a first conductive film over the first insulating layer, a fourth step of etching part of the first conductive film to form a first conductive layer, thereby forming a first region over the semiconductor layer that overlaps with the first conductive layer and a second region over the semiconductor layer that does not overlap with the first conductive layer, and a fifth step of performing first treatment on the conductive layer. The first treatment is plasma treatment in an atmosphere including a mixed gas of a first gas containing an oxygen element but not containing a hydrogen element, and a second gas containing a hydrogen element but not containing an oxygen element.

Embodiments of the invention include a method for fabricating a semiconductor device and the resulting structure. A substrate is provided. A plurality of metal portions are formed on the substrate, wherein the plurality of metal portions are arranged such that areas of the substrate remain exposed. A thin film layer is deposited on the plurality of metal portions and the exposed areas of the substrate. A dielectric layer is deposited, wherein the dielectric layer is in contact with portions of the thin film layer on the plurality of metal portions, and wherein the dielectric layer is not in contact with portions of the thin film layer on the exposed areas of the substrate such that one or more enclosed spaces are present between the thin film layer on the exposed areas of the substrate and the dielectric layer.

Embodiments of the invention include a method for fabricating a semiconductor device and the resulting structure. A substrate is provided. A plurality of metal portions are formed on the substrate, wherein the plurality of metal portions are arranged such that areas of the substrate remain exposed. A thin film layer is deposited on the plurality of metal portions and the exposed areas of the substrate. A dielectric layer is deposited, wherein the dielectric layer is in contact with portions of the thin film layer on the plurality of metal portions, and wherein the dielectric layer is not in contact with portions of the thin film layer on the exposed areas of the substrate such that one or more enclosed spaces are present between the thin film layer on the exposed areas of the substrate and the dielectric layer.

There is provided a method for fabricating a semiconductor device having the following structure, and comprising the steps of growing a first and a second nucleation layer on a substrate; depositing a binary layer over these nucleation layers; and annealing the binary layer to form a first contact area and a second contact area on the substrate, wherein the annealed binary layer comprises a group 14 element selected from Si, Ge and their combination thereof, and the annealed binary layer in the first and second contact areas are capable of providing a lower contact resistance for a current to flow in the device. This method serves to provide an intermediate layer which enables the fabrication process to become CMOS compatible.