A semiconductor device structure is provided. The semiconductor device structure includes a gate stack over a semiconductor substrate and a source/drain structure adjacent to the gate stack. The semiconductor device structure also includes a cap element over the source/drain structure. The cap element has a first top plane, and the source/drain structure has a second top plane. The first top plane of the cap element is wider than the second top plane of the source/drain structure. A surface orientation of the first top plane of the cap element and a surface orientation of a side surface of the cap element are different from each other. The surface orientation of the first top plane of the cap element is {311}.

A semiconductor device includes a channel pattern including first and second semiconductor patterns stacked on a substrate, a gate electrode covering top and lateral surfaces of the channel pattern and extending in a first direction, and including a first gate segment between the first semiconductor pattern and the second semiconductor pattern, a gate spacer covering a lateral surface of the gate electrode and including an opening exposing the channel pattern, and a first source/drain pattern on a side of the gate spacer and in contact with the channel pattern through the opening, the first source/drain pattern including a sidewall center thickness at a height of the first gate segment and at a center of the opening, and a sidewall edge thickness at the height of the first gate segment and at an edge of the opening, the sidewall edge thickness being about 0.7 to 1 times the sidewall center thickness.

A method for manufacturing an inverter circuit includes providing a semiconductor substrate and forming at least one dielectric trench isolation structure in the semiconductor substrate to divide the semiconductor substrate into first and second regions. A P+ doped portion and an N+ doped portion is formed in each of the first and second regions. Gate structure layers are then deposited over the semiconductor substrate. A first opening is formed in the gate structure layers over the P+ doped portion of a first region and a second opening is formed in the gate structure layers over the N+ doped portion of a second region. A gate dielectric layer is then formed on an inner side of the first and second openings. The surface of the semiconductor substrate in the first and second openings is etched. A semiconductor material is formed in the first and second openings by selective epitaxial growth.

There is provided a method of manufacturing a semiconductor device, which includes: forming a silicon film inside a recess formed in a surface of a workpiece by supplying a film forming gas containing silicon to the workpiece; subsequently, supplying a process gas, which includes a halogen gas for etching the silicon film and a roughness suppressing gas for suppressing roughening of a surface of the silicon film after being etched by the halogen gas, to the workpiece; etching the silicon film formed on a side wall of the recess to enlarge an opening width of the recess by applying thermal energy to the process gas and activating the process gas; and subsequently, filling silicon into the recess by supplying the film forming gas to the workpiece and depositing silicon on the silicon film remaining in the recess.

A semiconductor device may include first channels on a first region of a substrate and spaced apart from each other in a vertical direction substantially perpendicular to an upper surface of the substrate, second channels on a second region of the substrate and spaced apart from each other in the vertical direction, a first gate structure on the first region of the substrate and covering at least a portion of a surface of each of the first channels, and a second gate structure on the second region of the substrate and covering at least a portion of a surface of each of the second channels. The second channels may be disposed at heights substantially the same as those of corresponding ones of the first channels, and a height of a lowermost one of the second channels may be greater than a height of a lowermost one of the first channels.

A method may include providing a substrate having a surface that defines a substrate plane and a substrate feature that extends from the substrate plane; directing an ion beam comprising angled ions to the substrate at a non-zero angle with respect to a perpendicular to the substrate plane, wherein a first portion of the substrate feature is exposed to the ion beam and wherein a second portion of the substrate feature is not exposed to the ion beam; directing molecules of a molecular species to the substrate wherein the molecules of the molecular species cover the substrate feature; and providing a second species to react with the molecular species, wherein selective growth of a layer comprising the molecular species and the second species takes place such that a first thickness of the layer grown on the first portion is different from a second thickness grown on the second portion.

Deep trench isolation structures for high voltage semiconductor-on-insulator devices are disclosed herein. An exemplary deep trench isolation structure surrounds an active region of a semiconductor-on-insulator substrate. The deep trench isolation structure includes a first insulator sidewall spacer, a second insulator sidewall spacer, and a multilayer silicon-comprising isolation structure disposed between the first insulator sidewall spacer and the second insulator sidewall spacer. The multilayer silicon-comprising isolation structure includes a top polysilicon portion disposed over a bottom silicon portion. The bottom polysilicon portion is formed by a selective deposition process, while the top polysilicon portion is formed by a non-selective deposition process. In some embodiments, the bottom silicon portion is doped with boron.

The invention provides a method for fabricating a fin field effect transistor (FinFET), comprising: providing a substrate having a logic region and a large region; forming a plurality of fin structures in the logic region by removing a portion of the substrate in the logic region; forming an oxide layer on the substrate filling in-between the fin structures in the logic region; forming an first epitaxial structure in the large region by removing a portion of the substrate in the large region; exposing a portion of the fin structures and a portion of the epitaxial structure by removing a portion of the oxide layer; and forming a gate electrode on portions of the fin structures.

A method of concurrently forming source/drain contacts (CAs) and gate contacts (CBs) and device are provided. Embodiments include forming metal gates (PC) and source/drain (S/D) regions over a substrate; forming an ILD over the PCs and S/D regions; forming a mask over the ILD; concurrently patterning the mask for formation of CAs adjacent a first portion of each PC and CBs over a second portion of the PCs; etching through the mask, forming trenches extending through the ILD down to a nitride capping layer formed over each PC and a trench silicide (TS) contact formed over each S/D region; selectively growing a metal capping layer over the TS contacts formed over the S/D regions; removing the nitride capping layer from the second portion of each PC; and metal filling the trenches, forming the CAs and CBs.

An integrated circuit (IC) includes a semiconductor-on-insulator (SOI) substrate comprising a handle substrate, an insulator layer over the handle substrate, and a semiconductor device layer over the insulator layer. A logic device includes a logic gate arranged over the semiconductor device layer. The logic gate is arranged within a high κ dielectric layer. A memory cell includes a control gate and a select gate laterally adjacent to one another and arranged over the semiconductor device layer. A charge-trapping layer underlies the control gate.