In an LCD driver, in a high voltage resistant MISFET, end portions of a gate electrode run onto electric field relaxing insulation regions. Wires to become source wires or drain wires are formed on an interlayer insulation film of the first layer over the high voltage resistant MISFET. At this moment, when a distance from an interface between a semiconductor substrate and a gate insulation film to an upper portion of the gate electrode is defined as a, and a distance from the upper portion of the gate electrode to an upper portion of the interlayer insulation film on which the wires are formed is defined as b, a relation of a>b is established. In such a high voltage resistant MISFET structured in this manner, the wires are arranged so as not to be overlapped planarly with the gate electrode of the high voltage resistant MISFET.

A method for integrating a vertical transistor and a three-dimensional channel transistor includes forming narrow fins and wide fins in a substrate; forming a first source/drain (S/D) region at a base of the narrow fin and forming a gate dielectric layer and a gate conductor layer over the narrow fin and the wide fin. The gate conductor layer and the gate dielectric layer are patterned to form a vertical gate structure and a three-dimensional (3D) gate structure. Gate spacers are formed over sidewalls of the gate structures. A planarizing layer is deposited over the vertical gate structure and the 3D gate structure. A top portion of the narrow fin is exposed. S/D regions are formed on opposite sides of the 3D gate structure to form a 3D transistor, and a second S/D region is formed on the top portion of the narrow fin to form a vertical transistor.

A linear-shaped core structure of a first material is formed on an underlying material. A layer of a second material is conformally deposited over the linear-shaped core structure and exposed portions of the underlying material. The layer of the second material is etched so as to leave a filament of the second material on each sidewall of the linear-shaped core structure, and so as to remove the second material from the underlying material. The linear-shaped core structure of the first material is removed so as to leave each filament of the second material on the underlying material. Each filament of the second material provides a mask for etching the underlying material. Each filament of the second material can be selectively etched further to adjust its size, and to correspondingly adjust a size of a feature to be formed in the underlying material.

First, second, and third trenches are formed in a layer over a substrate. The third trench is substantially wider than the first and second trenches. The first, second, and third trenches are partially filled with a first conductive material. A first anti-reflective material is coated over the first, second, and third trenches. The first anti-reflective material has a first surface topography variation. A first etch-back process is performed to partially remove the first anti-reflective material. Thereafter, a second anti-reflective material is coated over the first anti-reflective material. The second anti-reflective material has a second surface topography variation that is smaller than the first surface topography variation. A second etch-back process is performed to at least partially remove the second anti-reflective material in the first and second trenches. Thereafter, the first conductive material is partially removed in the first and second trenches.

A semiconductor device is provided, including: a substrate having a first area and a second area; several first gate structures formed at the first area, and at least one of the first gate structures including a first hardmask on a first gate, and the first gate structure having a first gate length; several second gate structures formed at the second area, and at least one of the second gate structures including a second hardmask on a second gate, and the second gate structure having a second gate length. The first gate length is smaller than the second gate length, and the first hardmask contains at least a portion of nitrogen (N.sub.2)-based silicon nitride (SiN) which is free of OH concentration.

Semiconductor devices and methods of forming the same include forming mandrels on a first region and a second region of a gate layer. First spacers are formed on sidewalls of the mandrels. The mandrels are etched away to expose inner sidewalls of the first spacers. Second spacers are formed on sidewalls of the first spacers. First spacers in only the first region are etched away to expose inner sidewalls of the second spacers in the first region. The gate layer is etched using the remaining first spacers and the second spacers as a mask to form first gates in the first region and second gates in the second region. The first gates have a gate length than the second gates.

A chip includes multiple first transistors in a first region and multiple second transistors in a second region. A gap between adjacent first transistors has a same width as a gap between adjacent second transistors. Gates of the second transistors have a length substantially the same as twice a length of two adjacent first transistors plus the distance between said two adjacent first transistors.

A method includes, for example, a starting semiconductor structure comprising a plurality of material lines disposed over a hard mask, and the hard mask disposed over a patternable layer, forming a first protective layer over some of the plurality of material lines, the protected material lines and the unprotected material lines having a same corresponding first critical dimension, oxidizing the unprotected material lines so that the oxidized unprotected material lines have an increased second critical dimension greater than the first critical dimension, removing the first protective layer, forming a second protective layer over some of the plurality of protected material lines having the first critical dimension and some of the oxidized material lines having the second critical dimension, and oxidizing the unprotected material lines so that the oxidized unprotected material lines have an increased third critical dimension greater than the first critical dimension.

A method for forming semiconductor devices includes forming a highly doped region. A stack of alternating layers is formed on the substrate. The stack is patterned to form nanosheet structures. A dummy gate structure is formed over and between the nanosheet structures. An interlevel dielectric layer is formed. The dummy gate structures are removed. SG regions are blocked, and top sheets are removed from the nanosheet structures along the dummy gate trench. A bottommost sheet is released and forms a channel for a field effect transistor device by etching away the highly doped region under the nanosheet structure and layers in contact with the bottommost sheet. A gate structure is formed in and over the dummy gate trench wherein the bottommost sheet forms a device channel for the EG device.

Field-effect transistor (FET) devices are described herein that include one or more body contacts implemented near source, gate, drain (S/G/D) assemblies to improve the influence of a voltage applied at the body contact on the S/G/D assemblies. For example, body contacts can be implemented between S/G/D assemblies rather than on the ends of such assemblies. This can advantageously improve body contact influence on the S/G/D assemblies while maintaining a targeted size for the FET device.