A semiconductor device according to the present disclosure includes a fin structure over a substrate, a vertical stack of silicon nanostructures disposed over the fin structure, an isolation structure disposed around the fin structure, a germanium-containing interfacial layer wrapping around each of the vertical stack of silicon nanostructures, a gate dielectric layer wrapping around the germanium-containing interfacial layer, and a gate electrode layer wrapping around the gate dielectric layer.

A semiconductor device and a method of fabricating the semiconductor device are disclosed. The method includes forming a fin base on a substrate, epitaxially growing a S/D region on the fin base, forming a contact opening on the S/D region, forming a semiconductor nitride layer on a sidewall of the contact opening, performing a densification process on the semiconductor nitride layer to form a densified semiconductor nitride layer, forming a silicide layer on an exposed surface of the S/D region in the contact opening, forming a contact plug in the contact opening, and forming a via structure in the contact plug.

Integrated circuit devices and methods of forming the same are provided. The integrated circuit devices may include an upper transistor including an upper channel region on a substrate, a lower transistor between the substrate and the upper transistor, the lower transistor including a lower channel region, and a power line extending longitudinally in a first horizontal direction. At least one of the upper channel region or the lower channel region may extend longitudinally in a second horizontal direction that traverses the first horizontal direction, and the at least one of the upper channel region or the lower channel region may overlap the power line in a thickness direction.

The present disclosure relates to three-dimensional semiconductor devices. An example three-dimensional semiconductor device includes a back-side metal layer, a lower active region on the back-side metal layer, the lower active region including a lower channel pattern and a lower source drain pattern connected with the lower channel pattern, an upper active region on the lower active region, the upper active region including an upper channel pattern and an upper source drain pattern connected with the upper channel pattern, an interlayer insulating layer enclosing the lower and upper source drain patterns, a penetration conductive pattern extending through the interlayer insulating layer in a vertical direction, and an inhibitor covering a side surface of a lower portion of the penetration conductive pattern. The inhibitor includes a carbon atom.

An integrated circuit includes a first and second power rail extending in a first direction and being on a first level of a back-side of a substrate, a first and second active region and a first conductive line. The first power rail is configured to supply a first supply voltage. The second power rail is configured to supply a second supply voltage. The first and second active region extend in the first direction, and are on a second level of a front-side of the substrate opposite from the back-side. The first active region is overlapped by the first power rail. The second active region is overlapped by the second power rail. The first conductive line extends in the second direction, is on a third level of the back-side of the substrate, and overlaps the first and second active region.

A method of microfabrication includes epitaxially growing a first vertical channel structure of silicon-containing material on a first sacrificial layer of silicon containing material, the first sacrificial layer having etch selectivity with respect to the vertical channel structure. A core opening is directionally etched through the vertical channel structure to expose the first sacrificial layer, and the first sacrificial layer is isotropically etched through the core opening to form a first isolation opening for isolating the first vertical channel structure.

Systems and methods for a semiconductor device having a substrate material with a trench at a front side, a conformal dielectric material over at least a portion of the front side of the substrate material and in the trench, a fill dielectric material on the conformal dielectric material in the trench, and a conductive portion formed during front-end-of-line (FEOL) processing. The conductive portion may include an FEOL interconnect via extending through the fill dielectric material and at least a portion of the conformal dielectric material and having a front side portion defining a front side electrical connection extending beyond the front side of the semiconductor substrate material and a backside portion defining an active contact surface. The conductive portion may extend across at least a portion of the conformal dielectric material and the fill dielectric material and have a backside surface defining an active contact surface.

A semiconductor device includes first-type-channel field effect transistors (FETs) including a first first-type-channel FET including a first gate structure and a second first-type-channel FET including a second gate structure. The first first-type-channel FET has a smaller threshold voltage than the second first-type-channel FET. The first gate structure includes a first work function adjustment material (WFM) layer and the second gate structure includes a second WFM layer. At least one of thickness and material of the first and second WFM layers is different from each other.

In some embodiments, a semiconductor device is provided. The semiconductor device includes a semiconductor substrate having a first semiconductor material layer separated from a second semiconductor material layer by an insulating layer. A source region and a drain region are disposed in the first semiconductor material layer and spaced apart. A gate electrode is disposed over the first semiconductor material layer between the source region and the drain region. A first doped region having a first doping type is disposed in the second semiconductor material layer, where the gate electrode directly overlies the first doped region. A second doped region having a second doping type different than the first doping type is disposed in the second semiconductor material layer, where the second doped region extends beneath the first doped region and contacts opposing sides of the first doped region.

A semiconductor device may include first and second fin-shaped patterns on a substrate, that extend in a first direction, and are spaced apart from each other in a second direction. A first epitaxial pattern may be on the first fin-shaped pattern, and a second epitaxial pattern may be on the second fin-shaped pattern. A field insulating layer may be on the substrate, and may cover a sidewall of the first fin-shaped pattern, a sidewall of the second fin-shaped pattern, a part of a sidewall of the first epitaxial pattern, and a part of a sidewall of the second epitaxial pattern. The top surface of the field insulating layer may be higher than the bottom surface of the first epitaxial pattern and the bottom surface of the second epitaxial pattern.