A method for forming a semiconductor structure is provided. The method includes forming a fin structure over a substrate. The fin structure includes a protection layer and alternating first and second semiconductor layers over the protection layer. The method also includes etching the fin structure to form a source/drain recess, forming a sacrificial contact in the source/drain recess, forming a source/drain feature over the sacrificial contact in the source/drain recess, removing the first semiconductor layers of the fin structure, thereby forming a plurality of nanostructures, forming a gate stack wrapping around the nanostructures, removing the substrate thereby exposing the protection layer and the sacrificial contact and replacing the sacrificial contact with a contact plug.

Provided is a semiconductor structure with shared gated devices. The semiconductor structure comprises a substrate and a bottom dielectric isolation (BDI) layer on top of the substrate. The structure further comprises a pFET region that includes a p-doped Source-Drain epitaxy material and a first nanowire matrix above the BDI layer. The structure further comprises an nFET region that includes a n-doped Source-Drain epitaxy material and a second nanowire matrix above the BDI layer. The structure further comprises a conductive gate material on top of a portion of the first nanowire matrix and the second nanowire matrix. The structure further comprises a vertical dielectric pillar separating the pFET region and the nFET region. The vertical dielectric pillar extends downward through the BDI layer into the substrate. The vertical dielectric pillar further extends upward through the conductive gate material to a dielectric located above the gate region.

Techniques herein include methods of forming channel structures for field effect transistors having a channel current path parallel to a surface of a substrate. 3D in-situ horizontal or lateral growth of the channel and source/drain regions allows for a custom doping in the 3D horizontal nanosheet direction for NMOS and PMOS devices. An ultra-short channel length is achieved with techniques herein because the channel is epitaxially grown in the 3D horizontal nanosheet direction at the monolayer level. Since the channel is grown in a dielectric cavity, a precise channel cross sectional area can be tuned.

The present disclosure describes a semiconductor device with substantially uniform gate regions and a method for forming the same. The method includes forming a fin structure on a substrate, the fin structure including one or more nanostructures. The method further includes removing a portion of the fin structure to expose an end of the one or more nanostructures and etching the end of the one or more nanostructures with one or more etching cycles. Each etching cycle includes purging the fin structure with hydrogen fluoride (HF), etching the end of the one or more nanostructures with a gas mixture of fluorine (F.sub.2) and HF, and removing an exhaust gas mixture including an etching byproduct. The method further includes forming an inner spacer in the etched end of the one or more nanostructures.

A method includes depositing a first semiconductor layer and a second semiconductor layer over a substrate; patterning the first semiconductor layer, the second semiconductor layer, and the substrate to form a first nanostructure, a second nanostructure, and a semiconductor fin; forming a recess in the first nanostructure and the second nanostructure, the recess exposing the semiconductor fin; epitaxially growing a first layer in the recess, a first portion of the first layer being disposed along a first sidewall of the first nanostructure, a second portion of the first layer being disposed along the semiconductor fin, the first portion of the first layer comprising two sidewalls extending toward a middle of the recess, the first portion of the first layer further comprising a first surface most distal from the first sidewall and directly interposed between the two sidewalls, the first portion being physically separated from the second portion; and epitaxially growing a second layer over the first portion of the first layer and over the second portion of the first layer, the second layer physically connecting the first portion of the first layer to the second portion of the first layer.

A tunneling transistor includes a gate, an insulating layer placed on the gate, a carbon nanotube being semiconducting, a film-like structure, a source electrode, and a drain electrode. The carbon nanotube is placed on a surface of the insulating layer away from the gate. The film-like structure covers a portion of the carbon nanotube, and the film-like structure is a molybdenum disulfide film or a tungsten disulfide film. The source electrode is electrically connected to the film-like structure. The drain electrode is electrically connected to the carbon nanotube.

A semiconductor device includes a substrate, a 2-D material layer, source/drain contacts, and a gate electrode. The 2-D material layer is over the substrate, the 2-D material layer includes source/drain regions and a channel region between the source/drain regions, in which the 2-D material layer is made of a transition metal dichalcogenide (TMD). The source/drain contacts are in contact with source/drain regions of the 2-D material layer, in which a binding energy of transition metal atoms at the channel region of the 2-D material layer is different from a binding energy of the transition metal atoms at the source/drain regions of the 2-D material layer. The gate electrode is over the substrate.

A semiconductor device is provided. The semiconductor device includes: first, second and third active patterns on a logic cell region of a substrate and are spaced apart from each other in a first direction; first and second gate electrodes, the first gate electrode crossing the first active pattern and the second gate electrode crossing the second active pattern; a first separation pattern provided between the first and second active patterns; a second separation pattern provided between the second and third active patterns; a first gate insulating layer interposed between the first gate electrode and the first active pattern; and a first gate cutting pattern interposed between the first and second gate electrodes, and in contact with a top surface of the first separation pattern. The first separation pattern is wider than the second separation pattern, and the first gate insulating layer extends between the first gate electrode and the first separation pattern, and contacts side and top surfaces of the first separation pattern.

The semiconductor device including an active pattern on a substrate and extending in a first direction, a gate structure on the active pattern, including a gate electrode extending in a second direction different from the first direction, a source/drain pattern on at least one side of the gate structure, and a source/drain contact on the source/drain pattern and connected to the source/drain pattern, wherein with respect to an upper surface of the active pattern, a height of an upper surface of the gate electrode is same as a height of an upper surface of the source/drain contact, and the source/drain contact comprises a lower source/drain contact and an upper source/drain contact on the lower source/drain contact, may be provided.

A semiconductor device includes a semiconductor substrate, first and second stack units disposed over the semiconductor substrate, and a feature disposed between the first and second stack units. Each of the first and second stack units includes at least one stack that includes a conductive film and a dielectric film stacked on each other. The feature includes a plurality of repeating units and a plurality of separators disposed to alternate with the repeating units. Each of the repeating units includes an inner portion including a pair of conductive pillars, and an outer portion including a memory film and a channel film. A method for manufacturing the semiconductor device is also disclosed.