A semiconductor structure having doped wells and a method of forming is provided. The doped wells may utilize parallel implantation techniques and tilt implantation techniques to form wells having less lateral diffusion and less vertical doping.

The present disclosure generally relates to bilayer metal dichalcogenides, to processes for forming bilayer metal dichalcogenides, and to uses of bilayer metal dichalcogenides in devices for quantum electronics. In an aspect, a device is provided. The device includes a gate electrode, a substrate disposed over at least a portion of the gate electrode, and a bottom layer including a first metal dichalcogenide, the bottom layer disposed over at least a portion of the substrate. The device further includes a top layer including a second metal dichalcogenide, the top layer disposed over at least a portion of the bottom layer, the first metal dichalcogenide and the second metal dichalcogenide being the same or different. The device further includes a source electrode and a drain electrode disposed over at least a portion of the top layer.

A semiconductor structure may include a first nanosheet field-effect transistor formed on a first portion of a substrate, a second nanosheet field-effect transistor formed on a second portion of the substrate, and one or more metal contacts. The first field-effect transistor formed on the first portion of a substrate may include a first source drain epitaxy. A top surface of the first source drain epitaxy may be above a top surface of a top-most nanosheet channel layer. The second nanosheet field-effect transistor formed on the second portion of the substrate may include a second source drain epitaxy and a third source drain epitaxy. The second source drain epitaxy may be below the third source drain epitaxy. The third source drain epitaxy may be u-shaped and may be connected to at least one nanosheet channel layer.

A semiconductor device including a hybrid contact scheme for stacked FET is disclosed with integration of a BSPDN. A double-sided (both frontside and backside of the wafer) contact scheme with buried power rail (BPR) and backside power distribution network (BSPDN) provides optimum contact and interconnect. The stacked FET could include, for example, FINFET over FINFET, FINFET over nanosheet, or nanosheet over nanosheet.

A stacked semiconductor device comprising a lower source/drain epi located on top of a bottom dielectric layer. An isolation layer located on top of the lower source/drain epi and an upper source/drain epi located on top of the isolation layer. A lower electrical contact that is connected to the lower source/drain epi, wherein the lower electrical contact is in direct contact with multiple side surfaces of the lower source/drain epi.

A semiconductor device comprising at least one first gate all around channel having a horizontal physical orientation, wherein the at least one first gate all around channel is comprised of a first material, wherein the at least one first gate all around channel has a sidewall surface with (100) crystal orientation. At least one second gate all around channel having a vertical physical orientation, wherein the second channel is located above the at least one first gate all around channel, wherein the at least one second gate all around channel is comprised of a second material, wherein the at least one second gate all around channel has a sidewall surface with (110) crystal orientation. A gate metal enclosing the at least one first gate all around channel and the at least one second gate all around channel.

A semiconductor device includes first and second active regions parallel to each other and respectively extending in a first direction, an isolation layer between the first and second active regions, a first line structure and a second line structure overlapping the first and second active regions and the isolation layer, parallel to each other, and extending in a second direction, a first source/drain region on the first active region, and a second source/drain region on the second active region. The first line structure includes a first gate structure, a second gate structure, and a first insulating separation pattern between the first and second gate structures. The second line structure includes a third gate structure, a fourth gate structure, and a second insulating separation pattern between the third and fourth gate structures. The first and second insulating separation patterns are spaced apart from each other. The first insulating separation pattern has first and second side surfaces opposing each other, and third and fourth side surfaces opposing each other. At least one of the first and second side surfaces and at least one of the third and fourth side surfaces have different side profiles.

A semiconductor device includes an active fin protruding from a substrate; a plurality of channel layers on the active fin and spaced apart from each other in a vertical direction; a gate pattern intersecting the active fin and the plurality of channel layers; and source/drain regions on recessed regions of the active fin on both sides of the gate pattern. The gate pattern includes a gate dielectric layer, inner conductive layers, and a conductive liner. The inner conductive layers are disposed between the plurality of channel layers, and between the active fin and a lowermost channel layer among the plurality of channel layers. The conductive liner has a first thickness on an upper surface of an uppermost channel layer in the vertical direction, and at least one of the inner conductive layers have a second thickness in the vertical direction. The first thickness is less than the second thickness.

A method for fabricating a semiconductor device includes forming a fin structure that includes a plurality of semiconductor channel layers alternatively spaced apart from one another with a plurality of semiconductor sacrificial layers. The method further includes forming a semiconductor cladding layer extending along sidewalls of the fin structure. The method further includes patterning the semiconductor cladding layer to have a top surface with a highest point and a lowest point by performing at least one sequential combination of a first etching process and a second etching process. A vertical difference between the highest point and the lowest point is less than 3 nanometers.

A semiconductor device is provided. The semiconductor device includes: an active pattern provided on a substrate having an upper surface; an insulation pattern provided above the substrate and contacting an upper surface of the active pattern; channels spaced apart from each other along a direction perpendicular to the upper surface of the substrate, each of the channels including a material provided in the active pattern; and a gate structure contacting an upper surface of the insulation pattern, an upper surface of the channels, a lower surface of the channels, and sidewalls of the channels opposite to each other. A first distance between an upper surface of the active pattern and a lowermost one of the channels is greater than a second distance between an upper surface of one of the channels and a lower surface of an adjacent channel.