A CFET includes a fin that has a bottom channel portion, a top channel portion, and a channel isolator between the bottom channel portion and the top channel portion. The CFET further includes a source and drain stack that has a bottom source or drain (S/D) region connected to the bottom channel portion, a top S/D region connected to the top channel portion, a source-drain isolator between the bottom S/D region and the top S/D region. The CFET further includes a spacer foot physically connected to a base sidewall portion of the bottom S/D region and a buried S/D contact that is physically connected to an upper sidewall portion of the bottom S/D region. The CFET may further include a common gate around the bottom channel portion, around the top channel portion, and around the channel isolator.

A semiconductor device includes a substrate; a 1.sup.st transistor formed above the substrate, and having a 1.sup.st transistor stack including a plurality of 1.sup.st channel structures, a 1.sup.st gate structure surrounding the 1.sup.st channel structures, and 1.sup.st and 2.sup.nd source/drain regions at both ends of the 1.sup.st transistor stack in a 1.sup.st channel length direction; and a 2.sup.nd transistor formed above the 1.sup.st transistor in a vertical direction, and having a 2.sup.nd transistor stack including a plurality of 2.sup.nd channel structures, a 2.sup.nd gate structure surrounding the 2.sup.nd channel structures, and 3.sup.rd and 4.sup.th source/drain regions at both ends of the 2.sup.nd transistor stack in a 2.sup.nd channel length direction, wherein the 3.sup.rd source/drain region does not vertically overlap the 1.sup.st source/drain region or the 2.sup.nd source/drain region, and the 4.sup.th source/drain region does not vertically overlap the 1.sup.st source/drain region or the 2.sup.nd source/drain region.

A semiconductor device includes a gate line extending in a first direction, parallel to an upper surface of a semiconductor substrate; a first active region including a first channel region disposed below the gate line and including a first conductivity-type impurity; a second active region disposed to be separated from the first active region in the first direction, including a second channel region disposed below the gate line, and including the first conductivity-type impurity; and a plurality of metal wirings disposed at a first height level above the semiconductor substrate, wherein at least one metal wiring, among the plurality of metal wirings, is directly electrically connected to the first active region, no metal wirings at the first height level are electrically connected to the second active region, and at least one metal wiring, among the plurality of metal wirings, is connected to receive a signal applied to the gate line.

Single gate and dual gate FinFET devices suitable for use in an SRAM memory array have respective fins, source regions, and drain regions that are formed from portions of a single, contiguous layer on the semiconductor substrate, so that STI is unnecessary. Pairs of FinFETs can be configured as dependent-gate devices wherein adjacent channels are controlled by a common gate, or as independent-gate devices wherein one channel is controlled by two gates. Metal interconnects coupling a plurality of the FinFET devices are made of a same material as the gate electrodes. Such structural and material commonalities help to reduce costs of manufacturing high-density memory arrays.

An embodiment method includes: forming fins extending from a semiconductor substrate; depositing an inter-layer dielectric (ILD) layer on the fins; forming masking layers on the ILD layer; forming a cut mask on the masking layers, the cut mask including a first dielectric material, the cut mask having first openings exposing the masking layers, each of the first openings surrounded on all sides by the first dielectric material; forming a line mask on the cut mask and in the first openings, the line mask having slot openings, the slot openings exposing portions of the cut mask and portions of the masking layers, the slot openings being strips extending perpendicular to the fins; patterning the masking layers by etching the portions of the masking layers exposed by the first openings and the slot openings; and etching contact openings in the ILD layer using the patterned masking layers as an etching mask.

A semiconductor structure and a forming method thereof are provided. One form of a semiconductor structure includes: a first device structure, including a first substrate and a first device formed on the first substrate, the first device including a first channel layer structure located on the first substrate, a first device gate structure extending across the first channel layer structure, and a first source-drain doping region located in the first channel layer structure on two sides of the first device gate structure; and a second device structure, located on a front surface of the first device structure, including a second substrate located on the first device structure and a second device formed on the second substrate, the second device including a second channel layer structure located on the second substrate, a second device gate structure extending across the second channel layer structure, and a second source-drain doping region located in the second channel layer structure on two sides of the second device gate structure, where projections of the second channel layer structure and the first channel layer structure onto the first substrate intersect non-orthogonally. The electricity of the first device can be led out according to the present disclosure.

A semiconductor device may include a substrate including an active pattern extending in a first direction, a gate electrode running across the active pattern and extending in a second direction intersecting the first direction, a source/drain pattern on the active pattern and adjacent to a side of the gate electrode, an active contact in a contact hole exposing the source/drain pattern, an insulating pattern filling a remaining space of the contact hole in which the active contact is provided, a first via on the active contact, and a second via on the gate electrode. The active contact may include a first segment that fills a lower portion of the contact hole and a second segment that vertically protrudes from the first segment. The first via is connected to the second segment. The insulating pattern is adjacent in the first direction to the second via.

Self-aligned gate endcap (SAGE) architectures having local interconnects, and methods of fabricating SAGE architectures having local interconnects, are described. In an example, an integrated circuit structure includes a first gate structure over a first semiconductor fin, and a second gate structure over a second semiconductor fin. A gate endcap isolation structure is between the first and second semiconductor fins and laterally between and in contact with the first and second gate structures. A gate plug is over the gate endcap isolation structure and laterally between and in contact with the first and second gate structures. A local gate interconnect is between the gate plug and the gate endcap isolation structure, the local gate interconnect in contact with the first and second gate structures.

Methods for forming a semiconductor structure and semiconductor structures are described. The method comprises patterning a substrate to form a first opening and a second opening, the substrate comprising an n transistor and a p transistor, the first opening over the n transistor and the second opening over the p transistor; pre-cleaning the substrate; depositing a titanium silicide (TiSi) layer on the n transistor and on the p transistor by plasma-enhanced chemical vapor deposition (PECVD); optionally depositing a first barrier layer on the titanium silicide (TiSi) layer and selectively removing the first barrier layer from the p transistor; selectively forming a molybdenum silicide (MoSi) layer on the titanium silicide (TiSi) layer on the n transistor and the p transistor; forming a second barrier layer on the molybdenum silicide (MoSi) layer; and annealing the semiconductor structure. The method may be performed in a processing chamber without breaking vacuum.

Aspects of the present disclosure provide a method of manufacturing a three-dimensional (3D) semiconductor device. For example, the method can include forming a target structure, the target structure including a lower gate region, an upper gate region, and a separation layer disposed between and separating the lower gate region and the upper gate region. The method can also include forming a sacrificial contact structure extending vertically from the bottom gate region through the separation layer and the upper gate region to a position above the upper gate region, removing at least a portion of the sacrificial contact structure resulting in a lower gate contact opening extending from the position above the upper gate region to the bottom gate region, insulating a side wall surface of the lower gate contact opening, and filling the lower gate contact opening with a conductor to form a lower gate contact.