Semiconductor devices and methods of forming the same are provided. A semiconductor device according to the present disclosure includes a ferroelectric structure including a channel region and a source/drain region, a gate dielectric layer disposed over the channel region of the ferroelectric structure, a gate electrode disposed on the gate dielectric layer, and a source/drain contact disposed on the source/drain region of the ferroelectric structure. The ferroelectric structure includes gallium nitride, indium nitride, or indium gallium nitride. The ferroelectric structure is doped with a dopant.

A semiconductor device according to the present disclosure includes a first transistor and a second transistor. The first transistor includes a plurality of first channel members and a first gate structure wrapping around each of the plurality of first channel members. The second transistor includes a plurality of second channel members and a second gate structure disposed over the plurality of second channel members. Each of the plurality of first channel members has a first width and a first height smaller than the first width. Each of the plurality of second channel members has a second width and a second height greater than the second width.

A semiconductor device including a substrate including first and second regions, a first transistor on the first region and including a first semiconductor pattern protruding from the first region; a first gate structure covering an upper surface and sidewall of the first semiconductor pattern; first source/drain layers on the first semiconductor pattern at opposite sides of the first gate structure, upper surfaces of the first source/drain layers being closer to the substrate than an uppermost surface of the first gate structure; and a second transistor on the second region and including a second semiconductor pattern protruding from the second region; a second gate structure covering a sidewall of the second semiconductor pattern; and a second source/drain layer under the second semiconductor pattern; and a third source/drain layer on the second semiconductor pattern, wherein the upper surface of the first region is lower than the upper surface of the second region.

A semiconductor device includes an active fin formed to extend in a first direction, a gate formed on the active fin and extending in a second direction crossing the first direction, a source/drain formed on upper portions of the active fin and disposed at one side of the gate, an interlayer insulation layer covering the gate and the source/drain, a source/drain contact passing through the interlayer insulation layer to be connected to the source/drain and including a first contact region and a second contact region positioned between the source/drain and the first contact region, and a spacer layer formed between the first contact region and the interlayer insulation layer. A width of the second contact region in the first direction is greater than the sum of a width of the first contact region in the first direction and a width of the spacer layer in the first direction.

Systems, methods and apparatus are provided for a three-node access device in vertical three dimensional (3D) memory. An example method includes a method for forming arrays of vertically stacked memory cells, having horizontally oriented access devices and vertically oriented access lines. The method includes depositing alternating layers of a dielectric material and a sacrificial material in repeating iterations to form a vertical stack. An etchant process is used to form a first vertical opening exposing vertical sidewalls in the vertical stack adjacent a first region. The first region is selectively etched to form a first horizontal opening removing the sacrificial material a first horizontal distance back from the first vertical opening. A first source/drain material, a replacement channel material having backchannel passivation, and a second source/drain material are deposited in the first horizontal opening to form the three-node access device for a memory cell among the arrays of vertically stacked memory cells.

A multi-gate FinFET including a negative capacitor connected to one of its gates, a method of manufacturing the same, and an electronic device comprising the same are disclosed. In one aspect, the FinFET includes a fin extending in a first direction on a substrate, a first gate extending in a second direction crossing the first direction on the substrate on a first side of the fin to intersect the fin, a second gate opposite to the first gate and extending in the second direction on the substrate on a second side of the fin opposite to the first side to intersect the fin, a metallization stack provided on the substrate and above the fin and the first and second gates, and a negative capacitor formed in the metallization stack and connected to the second gate.

Memory devices, methods of manufacturing the same, and methods of accessing the same are provided. In one embodiment, the memory device may include a substrate, a back gate formed on the substrate, and a transistor. The transistor may include fins formed on opposite sides of the back gate on the substrate and a gate stack formed on the substrate and intersecting the fins. The memory device may further include a back gate dielectric layer formed on side and bottom surfaces of the back gate. The back gate dielectric layer may have a thickness reduced portion at a region facing the fins on one side of the gate stack.

A semiconductor device includes a fin region with long and short sides, a first field insulating layer including a top surface lower than that of the fin region and adjacent to a side surface of the short side of the fin region, a second field insulating layer including a top surface lower than that of the fin region and adjacent to a side surface of the long side of the fin region, an etch barrier pattern on the first field insulating layer, a first gate on the fin region and the second field insulating layer to face a top surface of the fin region and side surfaces of the long sides of the fin region. A second gate is on the etch barrier pattern overlapping the first field insulating layer. A source/drain region is between the first gate and the second gate, in contact with the etch barrier pattern.

Semiconductor device and the manufacturing method thereof are disclosed. An exemplary semiconductor device comprises first semiconductor stack over a substrate, wherein the first semiconductor stack includes first semiconductor layers separated from each other and stacked up along a direction substantially perpendicular to a top surface of the substrate; second semiconductor stack over the substrate, wherein the second semiconductor stack includes second semiconductor layers separated from each other and stacked up along the direction substantially perpendicular to the top surface of the substrate; inner spacers between edge portions of the first semiconductor layers and between edge portions of the second semiconductor layers; and a bulk source/drain (S/D) feature between the first semiconductor stack and the second semiconductor stack, wherein the bulk S/D feature is separated from the substrate by a first air gap, and the bulk S/D feature is separated from the inner spacers by second air gaps.

A method of fabricating a semiconductor device includes providing a dummy structure having a plurality of channel layers, an inner spacer disposed between adjacent channels of the plurality of channel layers and at a lateral end of the channel layers, and a gate structure including a gate dielectric layer and a metal layer interposing the plurality of channel layers. The dummy structure is disposed at an active edge adjacent to an active region. A metal gate etching process is performed to remove the metal layer from the gate structure while the gate dielectric layer remains disposed at a channel layer-inner spacer interface. After performing the metal gate etching process, a dry etching process is performed to form a cut region along the active edge. The gate dielectric layer disposed at the channel layer-inner spacer interface prevents the dry etching process from damaging a source/drain feature within the adjacent active region.