A method includes forming a first transistor and a second transistor over a semiconductor substrate, wherein the first transistor and the second transistor are vertically stacked. The method further includes exposing a backside of a first gate stack of the first transistor; forming a backside gate etch stop layer (ESL) on the backside of the first gate stack; patterning a contact opening through the backside gate ESL to expose the first gate stack; and forming a backside gate contact in the contact opening. The backside gate contact extends through the backside gate ESL to electrically connect to the first gate stack.

A 3D semiconductor device, the device including: a first level including single crystal first transistors, a first metal layer, and a first isolation layer; a second level including second transistors and a second isolation layer, where the first level is overlaid by the second level; a third level including single crystal third transistors, where the second level is overlaid by the third level, where the third level includes a third isolation layer, where the third level is bonded to the second level; and a power delivery path to the second transistors, where at least a portion of the power delivery path is connected to at least one of the first transistors.

Semiconductor device and the manufacturing method thereof are disclosed. An exemplary semiconductor device comprises a fin substrate having a first dopant concentration; an anti-punch through (APT) layer disposed over the fin substrate, wherein the APT layer has a second dopant concentration that is greater than the first dopant concentration; a nanostructure including semiconductor layers disposed over the APT layer; a gate structure disposed over the nanostructure and wrapping each of the semiconductor layers, wherein the gate structure includes a gate dielectric and a gate electrode; a first epitaxial source/drain (S/D) feature and a second epitaxial S/D feature disposed over the APT layer, wherein the gate structure is disposed between the first epitaxial S/D feature and the second epitaxial S/D feature; and an isolation layer disposed between the APT layer and the fin substrate, wherein a material of the isolation layer is the same as a material of the gate dielectric.

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.

A device includes a first nanostructure; a second nanostructure over the first nanostructure; a first high-k gate dielectric around the first nanostructure; a second high-k gate dielectric around the second nanostructure; and a gate electrode over the first and second high-k gate dielectrics. The gate electrode includes a first work function metal; a second work function metal over the first work function metal; and a first metal residue at an interface between the first work function metal and the second work function metal, wherein the first metal residue has a metal element that is different than a metal element of the first work function metal.

A method for manufacturing a semiconductor structure includes forming a plurality of semiconductor stack portions spaced apart from each other by a plurality of recesses, each of which includes two sacrificial layer portions and a channel layer portion disposed therebetween, in which the channel layer portion has a plurality of crystal planes and is formed with a first straight lateral surface which is aligned with one of the crystal planes that has a lowest etching rate for an etchant to be used for laterally etching the channel layer portion among those of the crystal planes of the channel layer portion which are able to expose to the recesses; and laterally etching the channel layer portion using the etchant to permit the channel layer portion to be formed with a second straight lateral surface.

Semiconductor device and the manufacturing method thereof are disclosed. An exemplary semiconductor device comprises a fin substrate having a first dopant concentration; an anti-punch through (APT) layer disposed over the fin substrate, wherein the APT layer has a second dopant concentration that is greater than the first dopant concentration; a nanostructure including semiconductor layers disposed over the APT layer; a gate structure disposed over the nanostructure and wrapping each of the semiconductor layers, wherein the gate structure includes a gate dielectric and a gate electrode; a first epitaxial source/drain (S/D) feature and a second epitaxial S/D feature disposed over the APT layer, wherein the gate structure is disposed between the first epitaxial S/D feature and the second epitaxial S/D feature; and an isolation layer disposed between the APT layer and the fin substrate, wherein a material of the isolation layer is the same as a material of the gate dielectric.

A method includes forming pillars that project upwardly from a substrate and comprise conductively-doped monocrystalline semiconductive material. The pillars comprise either one source/drain region or another source/drain region of a transistor of individual memory cells of the memory circuitry being formed. Conductively-doped monocrystalline semiconductor material is grown from a top and sidewalls of the pillars to form conductive monocrystalline coverings that are individually directly above the top and circumferentially about the sidewalls of the individual pillars. Digitlines are formed that are individually above and directly electrically coupled to a plurality of the individual pillars of the another source/drain regions through the epitaxially-grown conductive monocrystalline covering that is directly there-above. Storage elements are formed to be above and electrically coupled to the individual pillars of the one source/drain regions through the epitaxially-grown conductive monocrystalline covering that is directly there-above. Structures are disclosed.

A memory cell includes a transistor including a memory film extending along a word line; a channel layer extending along the memory film, wherein the memory film is between the channel layer and the word line; a source line extending along the memory film, wherein the memory film is between the source line and the word line; a first contact layer on the source line, wherein the first contact layer contacts the channel layer and the memory film; a bit line extending along the memory film, wherein the memory film is between the bit line and the word line; a second contact layer on the bit line, wherein the second contact layer contacts the channel layer and the memory film; and an isolation region between the source line and the bit line.