A semiconductor device is provided which includes a first fin-type pattern including a first side surface and a second side surface opposite to each other, a first trench of a first depth adjacent to the first side surface, a second trench of a second depth adjacent to the second side surface. The second depth differs from the first depth, and a first field insulating film partially fills the first trench and a second field insulating film partially fills the second trench. The first fin-type pattern has a lower portion, and an upper portion having a narrower width than the lower portion, and has a first stepped portion on a boundary between the upper portion and the lower portion. The first field insulating film includes a first lower field insulating film in contact with the lower portion, and a first upper field insulating film in contact with the upper portion.

A method for forming nanowires includes forming a plurality of epitaxial layers on a substrate, the layers including alternating material layers with high and low Ge concentration and patterning the plurality of layers to form fins. The fins are etched to form recesses in low Ge concentration layers to form pillars between high Ge concentration layers. The pillars are converted to dielectric pillars. A conformal material is formed in the recesses and on the dielectric pillars. The high Ge concentration layers are condensed to form hexagonal Ge wires with (111) facets. The (111) facets are exposed to form nanowires.

A method for forming nanowires includes forming a plurality of epitaxial layers on a substrate, the layers including alternating material layers with high and low Ge concentration and patterning the plurality of layers to form fins. The fins are etched to form recesses in low Ge concentration layers to form pillars between high Ge concentration layers. The pillars are converted to dielectric pillars. A conformal material is formed in the recesses and on the dielectric pillars. The high Ge concentration layers are condensed to form hexagonal Ge wires with (111) facets. The (111) facets are exposed to form nanowires.

The present description relates the formation of a first level interlayer dielectric material layer within a non-planar transistor, which may be formed by a spin-on coating technique followed by oxidation and annealing. The first level interlayer dielectric material layer may be substantially void free and may exert a tensile strain on the source/drain regions of the non-planar transistor.

A method for fabricating a semiconductor device includes forming a first mask on a substrate, forming a first side wall of a fin by performing a first etching of the substrate using the first mask, forming a second mask on the substrate, the second mask being different from the first mask, and forming a second side wall of the fin by performing a second etching of the substrate using the second mask.

According to one embodiment, a semiconductor device includes an element isolation insulating film, a gate electrode film, source/drain regions, a channel region, and an air gap. The element isolation insulating film partitions an element arrangement area on one main face side of a semiconductor substrate. The channel region is disposed near a surface of the semiconductor substrate below the gate electrode film. The air gap is disposed at a region of the element isolation insulating film contacting with the channel region.

A semiconductor device capable of adjusting profiles of a gate electrode and a gate spacer by implanting or doping an element semiconductor material into an interlayer insulating layer may be provided. The semiconductor device may include a gate spacer on a substrate, the gate spacer defining a trench, a gate electrode filling the trench, and an interlayer insulating layer on the substrate, which surrounds the gate spacer, and at least a portion of which includes germanium.

A fin field effect transistor (FinFET) having a tunable tensile strain and an embodiment method of tuning tensile strain in an integrated circuit are provided. The method includes forming a source/drain region on opposing sides of a gate region in a fin, forming spacers over the fin, the spacers adjacent to the source/drain regions, depositing a dielectric between the spacers; and performing an annealing process to contract the dielectric, the dielectric contraction deforming the spacers, the spacer deformation enlarging the gate region in the fin.

A semiconductor device and method of formation are provided herein. A semiconductor device includes a fin having a doped region, in some embodiments. The semiconductor device includes a gate over a channel portion of the fin. The gate including a gate electrode over a gate dielectric between a first sidewall spacer and a second sidewall spacer. The first sidewall spacer includes an initial first sidewall spacer over a first portion of a dielectric material. The second sidewall spacer includes an initial second sidewall spacer over a second portion of the dielectric material.

A method of forming a semiconductor device is disclosed. At least one suspended first semiconductor nanowire and two first semiconductor blocks at two ends of the first semiconductor nanowire are formed in a first area, and at least one suspended second semiconductor nanowire and two second semiconductor blocks at two ends of the second semiconductor nanowire are formed in a second area. A transforming process is performed, so the first semiconductor nanowire is transformed into a nanowire with stress, and the second semiconductor blocks are simultaneously transformed into two blocks with stress. First and second gate dielectric layers are formed respectively on surfaces of the nanowire with stress and the second semiconductor nanowire. First and second gates are formed respectively across the nanowire with stress and the second semiconductor nanowire.