The present invention relates generally to semiconductors, and more particularly, to a structure and method of minimizing shorting between epitaxial regions in small pitch fin field effect transistors (FinFETs). In an embodiment, a dielectric region may be formed in a middle portion of a gate structure. The gate structure be formed using a gate replacement process, and may cover a middle portion of a first fin group, a middle portion of a second fin group and an intermediate region of the substrate between the first fin group and the second fin group. The dielectric region may be surrounded by the gate structure in the intermediate region. The gate structure and the dielectric region may physically separate epitaxial regions formed on the first fin group and the second fin group from one another.

A method of forming a gate structure for a semiconductor device that includes forming first spacers on the sidewalls of replacement gate structures that are present on a fin structure, wherein an upper surface of the first spacers is offset from an upper surface of the replacement gate structure, and forming at least second spacers on the first spacers and the exposed surfaces of the replacement gate structure. The method may further include substituting the replacement gate structure with a functional gate structure having a first width portion in a first space between adjacent first spacers, and a second width portion having a second width in a second space between adjacent second spacers, wherein the second width is greater than the first width.

Gate structures formed from substantially rectangular shaped gate structure layout shapes positioned on a gate horizontal grid having at least seven gate gridlines within a region. A first-metal layer including first-metal structures formed from substantially rectangular shaped first-metal structure layout shapes is formed above top surfaces of the gate structures within the region. The first-metal structure layout shapes are positioned on a first-metal vertical grid having at least eight first-metal gridlines. At least six contact structures are formed from substantially rectangular shaped contact structure layout shapes in physical and electrical contact with corresponding ones of at least six of the gate structures. A total number of first-transistor-type-only gate structures equals a total number of second-transistor-type-only gate structures within the region. At least four transistors of a first transistor type and at least four transistors of a second transistor type collectively form part of a logic circuit within the region.

Gate structures are positioned within a region in accordance with a gate horizontal grid that includes at least seven gate gridlines separated from each other by a gate pitch of less than or equal to about 193 nanometers. Each gate structure has a substantially rectangular shape with a width of less than or equal to about 45 nanometers and is positioned to extend lengthwise along a corresponding gate gridline. Each gate gridline has at least one gate structure positioned thereon. A first-metal layer is formed above top surfaces of the gate structures within the region and includes first-metal structures positioned in accordance with a first-metal vertical grid that includes at least eight first-metal gridlines. Each first-metal structure has a substantially rectangular shape and is positioned to extend along a corresponding first-metal gridline. At least six contact structures of substantially rectangular shape contact the at least six gate structures.

There is provided a semiconductor device having LDMOS transistors embedded in a semiconductor substrate to boost source-drain breakdown voltage, with arrangements to prevent fluctuations of element characteristics caused by electric field concentration so that the reliability of the semiconductor device is improved. A trench is formed over the upper surface of a separation insulating film of each LDMOS transistor, the trench having a gate electrode partially embedded therein. This structure prevents electric field concentration in the semiconductor substrate near the source-side edge of the separation insulating film.

Described is an apparatus forming complementary tunneling field effect transistors (TFETs) using oxide and/or organic semiconductor material. One type of TFET comprises: a substrate; a doped first region, formed above the substrate, having p-type material selected from a group consisting of Group III-V, IV-IV, and IV of a periodic table; a doped second region, formed above the substrate, having transparent oxide n-type semiconductor material; and a gate stack coupled to the doped first and second regions. Another type of TFET comprises: a substrate; a doped first region, formed above the substrate, having p-type organic semiconductor material; a doped second region, formed above the substrate, having n-type oxide semiconductor material; and a gate stack coupled to the doped source and drain regions. In another example, TFET is made using organic only semiconductor materials for active regions.

Gate structures are positioned within a region in accordance with a gate horizontal grid that includes at least seven gate gridlines separated from each other by a gate pitch of less than or equal to about 193 nanometers. Each gate structure has a substantially rectangular shape with a width of less than or equal to about 45 nanometers and is positioned to extend lengthwise along a corresponding gate gridline. Each gate gridline has at least one gate structure positioned thereon. A first-metal layer is formed above top surfaces of the gate structures within the region and includes first-metal structures positioned in accordance with a first-metal vertical grid that includes at least eight first-metal gridlines. Each first-metal structure has a substantially rectangular shape and is positioned to extend along a corresponding first-metal gridline. At least six contact structures of substantially rectangular shape contact the at least six gate structures.

Structures and formation methods of a semiconductor device structure are provided. The semiconductor device structure includes a fin structure over a semiconductor substrate. The semiconductor device structure also includes a gate stack covering a portion of the fin structure. The gate stack includes a first portion and a second portion adjacent to the fin structure, and the first portion is wider than the second portion.

A semiconductor structure and a method for forming the same are provided. The semiconductor structure includes a gate stack structure formed over a substrate. The gate stack structure includes a gate electrode structure having a first portion and a second portion and a first conductive layer below the gate electrode structure. In addition, the first portion of the gate electrode structure is located over the second portion of the gate electrode structure, and a width of a top surface of the first portion of the gate electrode structure is greater than a width of a bottom surface of the second portion of the gate electrode structure.

A semiconductor device includes a pillar-shaped semiconductor layer and a first gate insulating film around the pillar-shaped semiconductor layer. A metal gate electrode is around the first gate insulating film and a metal gate line is connected to the gate electrode. A second gate insulating film is around a sidewall of an upper portion of the pillar-shaped semiconductor layer and a first contact made of a second metal surrounds the second gate insulating film. An upper portion of the first contact is electrically connected to an upper portion of the pillar-shaped semiconductor layer, and a third contact resides on the metal gate line. A lower portion of the third contact is made of the second metal.