A multi-channel semiconductor-on-insulator (SOI) transistor includes a substrate having an electrically insulating layer thereon and a semiconductor active layer on the electrically insulating layer. A vertical stack of spaced-apart insulated gate electrodes, which are buried within the semiconductor active layer, is also provided. This vertical stack includes a first insulated gate electrode extending adjacent the electrically insulating layer and an (N−1)th insulated gate electrode that is spaced from a surface of the semiconductor active layer, where N is a positive integer greater than two. An Nth insulated gate electrode is provided on the surface of the semiconductor active layer. A pair of source/drain regions are provided within the semiconductor active layer. These source/drain regions extend adjacent opposing sides of the vertical stack of spaced-apart insulated gate electrodes. In some of these aspects, the semiconductor active layer extends between the pair of source/drain regions and the electrically insulating layer, whereas the first insulated gate electrode contacts the electrically insulating layer.

The present invention proposes a semiconductor device, its manufacturing method and to an electronic apparatus thereof equipped with the semiconductor device where it becomes possible to make a CMOS type solid-state imaging device, an imager area formed with a MOS transistor of an LDD structure without having a metal silicide layer of a refractory metal, an area of DRAM cells and the like into a single semiconductor chip. According to the present invention, a semiconductor device is constituted such that an insulating film having a plurality of layers is used, sidewalls at the gate electrodes are formed by etchingback the insulating film of the plurality of layers or a single layer film in the region where metal silicide layers are formed and in the region where the metal silicide layers are not formed, sidewalls composed of an upper layer insulating film is formed on a lower layer insulating film whose surface is coated or the insulating film of the plurality of layers remain unchanged.

A semiconductor device including: a first conductivity type transistor and a second conductivity type transistor, wherein each of the first conductivity type transistor and the second conductivity type includes agate insulating film formed on a base, a metal gate electrode formed on the gate insulating film, and side wall spacers formed at side walls of the metal gate electrode, wherein the gate insulating film is made of a high dielectric constant material, and wherein offset spacers are formed between the side walls of the metal gate electrode and the inner walls of the side wall spacers in any one of the first conductivity type transistor and the second conductivity type transistor, or offset spacers having different thicknesses are formed in the first conductivity type transistor and the second conductivity type transistor.

An integrated circuit and method with a single stress liner film and a stress relief implant where the distance of the stress relief implant to the transistors is adjusted for improved transistor performance.

A semiconductor device include a substrate including a peripheral region, a first active pattern provided on the peripheral region of the substrate, the first active pattern having an upper portion including first semiconductor patterns and second semiconductor patterns which are alternately stacked, a first gate electrode intersecting the first active pattern, a pair of first source/drain patterns provided at both sides of the first gate electrode, respectively, and a first gate insulating layer disposed between the first gate electrode and the first active pattern. The first gate insulating layer includes a first insulating layer formed on the first active pattern, a second insulating layer formed on the first insulating layer, and a high-k dielectric layer formed on the second insulating layer. The first gate insulating layer contains a first dipole element including lanthanum (La), aluminum (Al), or a combination thereof.

A 3D semiconductor device a first level, where the first level includes a first layer which includes first transistors, where the first level includes a second layer, the second layer including first interconnections; a second level overlaying the first level, where the second level includes a third layer which includes second transistors, and where the second level includes a fourth layer, the fourth layer including second interconnections and a plurality of connection paths, where the plurality of connection paths provides connections from a plurality of the first transistors to a plurality of the second transistors, where the second level is bonded to the first level, where the bonded includes oxide to oxide bond regions, where the bonded includes metal to metal bond regions, where the second level includes at least one first ElectroStatic Discharge (ESD) circuit, and where the first level includes at least one second ESD circuit.

A vertical DMOS device implements one or more deep silicon via (DSV) plugs, thereby significantly reducing the layout area and on-resistance (RDS.sub.ON) of the device. The DSV plugs extend through a semiconductor substrate to contact a conductively doped buried diffusion region, which forms the drain of the vertical DMOS device. Methods for fabricating the vertical DMOS device are compatible with conventional sub-micron VLSI processes, such that the vertical DMOS device can be readily fabricated on the same integrated circuit as CMOS devices and analog devices, such as lateral double-diffused MOS (LDMOS) devices.

A method includes providing a substrate having a channel region, forming a gate stack layer over the channel region, forming a patterned hard mask over the gate stack layer, etching a top portion of the gate stack layer through openings in the patterned hard mask with a first etchant, etching a middle portion and a bottom portion of the gate stack layer with a second etchant that includes a passivating gas. A gate stack is formed with a passivation layer deposited on sidewalls of the gate stack. The method also includes etching the gate stack with a third etchant, thereby removing a bottom portion of the passivation layer and recessing a bottom portion of the gate stack.

An integrated circuit with a thick TiN metal gate with a work function greater than 4.85 eV and with a thin TiN metal gate with a work function less than 4.25 eV. An integrated circuit with a replacement gate PMOS TiN metal gate transistor with a workfunction greater than 4.85 eV and with a replacement gate NMOS TiN metal gate transistor with a workfunction less than 4.25 eV. An integrated circuit with a gate first PMOS TiN metal gate transistor with a workfunction greater than 4.85 eV and with a gate first NMOS TiN metal gate transistor with a workfunction less than 4.25 eV.

An integrated circuit and method with dual stress liners and with NMOS transistors with gate overhang of active that is longer than the minimum design rule and with PMOS transistors with gate overhang of active that are not longer than the minimum design rule.