A method for fabricating a Fin-FET device includes forming a fin structure on a semiconductor substrate having two peripheral regions and a core region, forming a plurality of dummy gate structures across the fin structure in the core region with each including a dummy gate electrode layer on top and sidewall surfaces of the fin structure, and forming a barrier structure across the fin structure in each peripheral region. The method also includes forming a plurality of source/drain regions in the fin structure between neighboring barrier structure and dummy gate structure and also between neighboring dummy gate structures, and forming a first interlayer dielectric layer at least on the fin structure to cover sidewall surfaces of the dummy gate structures and the barrier structures. Further, the method includes removing the dummy gate electrode layers to form a plurality of openings and forming a metal gate electrode layer in each opening.

Disclosed are a three-dimensional semiconductor device and a method of fabricating the same. The semiconductor device includes: a first active region on a substrate, the first active region including a pair of lower source/drain regions and a lower channel structure; a second active region on the first active region, the second active region including a pair of upper source/drain regions and an upper channel structure; and a gate electrode on the lower and upper channel structures. The gate electrode includes: first and second metal structures, which are respectively provided adjacent bottom and top surfaces of semiconductor layers of the lower and upper channel structures.

A semiconductor device of the present invention includes a semiconductor layer of a first conductivity type having a cell portion and an outer peripheral portion disposed around the cell portion, and a surface insulating film disposed in a manner extending across the cell portion and the outer peripheral portion, and in the cell portion, formed to be thinner than a part in the outer peripheral portion.

A method includes providing a silicon carbide substrate, wherein a gate trench extends from a main surface of the silicon carbide substrate into the silicon carbide substrate and wherein a gate dielectric is formed on at least one sidewall of the gate trench, and forming a gate electrode in the gate trench, the gate electrode including a metal structure and a semiconductor layer between the metal structure and the gate dielectric.

Provided is a light extraction substrate capable of achieving both light extraction efficiency and preservability. Before forming a cap layer, a step of reducing in-membrane water content such that the in-membrane water content of a layer formed between a gas barrier layer and the cap layer is less than 1.0×10.sup.15/mg is performed. The in-membrane water content of less than 1.0×10.sup.15/mg is maintained until at least a step of forming the cap layer after the step of reducing the in-membrane water content, and the cap layer is then formed through a dry process.

A semiconductor device of the present invention includes a semiconductor layer of a first conductivity type having a cell portion and an outer peripheral portion disposed around the cell portion, formed with a gate trench at a surface side of the cell portion, and a gate electrode buried in the gate trench via a gate insulating film, forming a channel at a portion lateral to the gate trench at ON-time, the outer peripheral portion has a semiconductor surface disposed at a depth position equal to or deeper than a depth of the gate trench, and the semiconductor device further includes a voltage resistant structure having a semiconductor region of a second conductivity type formed in the semiconductor surface of the outer peripheral portion.

A semiconductor device includes a transistor configuration including first and second gate electrodes, each of the first and second gate electrodes having at least a bottom layer and an upper layer including polycrystalline silicon grains, wherein the first gate electrode is a nMOS gate electrode formed in an nMOS region of the transistor configuration, wherein the polycrystalline silicon grains included in the bottom layer of the first gate electrode have a greater particle diameter than the polycrystalline grains included in the upper layer of the second gate electrode.

An enhanced switch device and a manufacturing method therefor. The method comprises: providing a substrate, and forming a nitride transistor structure on the substrate; fabricating and forming a dielectric layer on the nitride transistor structure, on which a gate region is defined; forming a groove structure on the gate region; depositing a p-type semiconductor material in the groove; removing the p-type semiconductor material outside the gate region on the dielectric layer; etching the dielectric layer in another position than the gate region on the dielectric layer to form two ohmic contact regions; and forming a source electrode and a drain electrode on the two ohmic contact regions, respectively.

A semiconductor device includes a semiconductor substrate, a body region of a first conductivity type in the substrate, a source region of a second conductivity type adjacent the body region, and a trench extending into the substrate. The trench contains a polysilicon gate electrode insulated from the substrate. The device further includes a dielectric layer on the substrate, a gate metallization on the dielectric layer and covering part of the substrate and a source metallization on the dielectric layer and electrically connected to the source region. The gate metallization includes two spaced apart fingers. The source metallization is spaced apart from the gate metallization and covers a different part of the substrate than the gate metallization. A metal-filled groove in the polysilicon gate electrode is electrically connected to the two spaced apart fingers, and extends along a length of the trench directly underneath at least part of the source metallization.

A trench metal-oxide-semiconductor field effect transistor (MOSFET), in accordance with one embodiment, includes a drain region, a plurality of gate regions disposed above the drain region, a plurality of gate insulator regions each disposed about a periphery of a respective one of the plurality of gate regions, a plurality of source regions disposed in recessed mesas between the plurality of gate insulator regions, a plurality of body regions disposed in recessed mesas between the plurality of gate insulator regions and between the plurality of source regions and the drain region. The MOSFET also includes a plurality of body contact regions disposed in the each body region adjacent the plurality of source regions, a plurality of source/body contact spacers disposed between the plurality of gate insulator regions above the recessed mesas, a source/body contact disposed above the source/body contact spacers, and a plurality of source/body contact, plugs disposed between the source/body contact spacers and coupling the source/body contact to the plurality of body contact regions and the plurality of source regions.