A semiconductor device includes an active pattern including a lower pattern extending a first direction and a plurality of sheet patterns spaced apart from the lower pattern in a second direction, the plurality of sheet patterns including an uppermost sheet pattern, a plurality of gate structures disposed to be spaced apart from each other in the first direction on the active pattern and including gate electrodes extending in a third direction and gate spacers on sidewalls of the gate electrodes and a source/drain pattern disposed between the gate structures adjacent to each other and including a semiconductor liner film and a semiconductor filling film on the semiconductor liner film, wherein the semiconductor liner film covers a portion of an upper surface of an uppermost sheet pattern.

A method includes alternately stacking first semiconductor layers and second semiconductor layers over a substrate, patterning the first and second semiconductor layers into a fin structure, forming a dummy gate structure across the fin structure, depositing gate spacers over sidewalls of the dummy gate structure, removing the dummy gate structure to form a recess, removing the first semiconductor layers, depositing an interfacial layer wrapping the second semiconductor layers, depositing a high-k dielectric layer over the interfacial layer and over the sidewalls of the gate spacers, depositing a first gate electrode over the high-k dielectric layer, recessing the first gate electrode and the high-k dielectric layer to expose a top portion of the sidewalls of the gate spacers, depositing a low-k dielectric layer over the recessed high-k dielectric layer, and depositing a second gate electrode over the first gate electrode.

A semiconductor device includes an insulating substrate, a silicon layer on the insulating substrate, a dopant layer on the silicon layer, a buried spacer on a side surface of the dopant layer, a channel pattern on the dopant layer, the channel pattern comprising a plurality of semiconductor patterns vertically stacked and spaced apart from each other, a source/drain pattern on the buried spacer, the source/drain pattern connected to the channel pattern, a gate electrode on the channel pattern, the gate electrode comprising a plurality of inner electrodes between the semiconductor patterns, respectively, a lower power interconnection line in a lower portion of the insulating substrate, and a backside contact extending into the insulating substrate and the silicon layer to electrically connect the lower power interconnection line to the source/drain pattern. A side surface of the backside contact is in contact with the silicon layer and the buried spacer.

A transistor and a manufacturing method. The transistor includes a semiconductor base substrate, an active structure, a dielectric structure, and a gate stack structure. The active structure is formed on the semiconductor base substrate. The active structure includes a source region, a drain region, and a channel region located between the source region and the drain region. The channel region includes at least two nanostructures stacked in a thickness direction of the semiconductor base substrate. In the channel region, a bottom nanostructure has a greater width than other nanostructures. The dielectric structure is formed between the semiconductor base substrate and the active structure. The dielectric structure is in contact with the bottom nanostructure. The gate stack structure is formed on a surface of the bottom nanostructure not in contact with the dielectric structure, and the gate stack surrounds a periphery of the other nanostructures.

Methods for forming packaged semiconductor devices including backside power rails and packaged semiconductor devices formed by the same are disclosed. In an embodiment, a device includes a first integrated circuit device including a first transistor structure in a first device layer; a front-side interconnect structure on a front-side of the first device layer; and a backside interconnect structure on a backside of the first device layer, the backside interconnect structure including a first dielectric layer on the backside of the first device layer; and a first contact extending through the first dielectric layer to a source/drain region of the first transistor structure; and a second integrated circuit device including a second transistor structure in a second device layer; and a first interconnect structure on the second device layer, the first interconnect structure being bonded to the front-side interconnect structure by dielectric-to-dielectric and metal-to-metal bonds.

A semiconductor structure includes an epitaxial region having a front side and a backside. The semiconductor structure includes an amorphous layer formed over the backside of the epitaxial region, wherein the amorphous layer includes silicon. The semiconductor structure includes a first silicide layer formed over the amorphous layer. The semiconductor structure includes a first metal contact formed over the first silicide layer.

A method for manufacturing a gate-all-around TFET device. The method comprises: forming, on a substrate, a channel stack comprising channel layer(s) and sacrificial layer(s) that alternate with each other; forming, on the substrate, a dummy gate astride the channel stack; forming a first spacer at a surface of the dummy gate; etching the sacrificial layer(s) to form recesses on side surfaces of the channel stack; forming second spacers in the recesses, respectively; fabricating a source and a drain separately, where a region for fabricating the source is shielded by a dielectric material when fabricating the drain, and a region for fabricating the drain is shielded by another dielectric material when fabricating the source; etching the dummy gate and the sacrificial layer(s) to form a space for a surrounding gate; and fabricating a surrounding dielectric-metal gate in the space.

Semiconductor device and the manufacturing method thereof are disclosed. An exemplary method comprises forming a first stack structure and a second stack structure in a first area over a substrate, wherein each of the stack structures includes semiconductor layers separated and stacked up; depositing a first interfacial layer around each of the semiconductor layers of the stack structures; depositing a gate dielectric layer around the first interfacial layer; forming a dipole oxide layer around the gate dielectric layer; removing the dipole oxide layer around the gate dielectric layer of the second stack structure; performing an annealing process to form a dipole gate dielectric layer for the first stack structure and a non-dipole gate dielectric layer for the second stack structure; and depositing a first gate electrode around the dipole gate dielectric layer of the first stack structure and the non-dipole gate dielectric layer of the second stack structure.

The present disclosure describes a semiconductor device and methods for forming the same. The semiconductor device includes nanostructures on a substrate and a source/drain region in contact with the nanostructures. The source/drain region includes epitaxial end caps, where each epitaxial end cap is formed at an end portion of a nanostructure of the nanostructures. The source/drain region also includes an epitaxial body in contact with the epitaxial end caps and an epitaxial top cap formed on the epitaxial body. The semiconductor device further includes gate structure formed on the nanostructures.

A method includes forming a first sacrificial layer over a substrate, and forming a sandwich structure over the first sacrificial layer. The sandwich structure includes a first isolation layer, a two-dimensional material over the first isolation layer, and a second isolation layer over the two-dimensional material. The method further includes forming a second sacrificial layer over the sandwich structure, forming a first source/drain region and a second source/drain region on opposing ends of, and contacting sidewalls of, the two-dimensional material, removing the first sacrificial layer and the second sacrificial layer to generate spaces, and forming a gate stack filling the spaces.