A semiconductor structure comprises a substrate defining a first axis and a second axis orthogonal to the first axis, a first nanosheet region disposed on the substrate and defining a first channel width along the second axis, a first gate disposed around the first nanosheet region, a second nanosheet region disposed on the substrate and defining a second channel width along the second axis less than the first channel width of the first nanosheet region and a second gate disposed around the second nanosheet region.

A semiconductor device and a method for manufacturing the same, and a NAND memory device are disclosed. The method comprises: forming a substrate that comprises a first active region and an isolation region; forming a first groove between the isolation region and the first channel region, the first groove being partially located in the isolation region, and not penetrating through the isolation region; forming a first gate insulating layer covering the first groove and the first channel region; forming a first gate on the first gate insulating layer, the first gate covering the first channel region and filling the first groove.

A semiconductor structure is provided. The semiconductor structure includes a substrate containing a first active region in a first region of the substrate and a second active region in a second region of the substrate, a plurality of first gate structures over the first active region each including a first gate stack having a first high-k gate dielectric and a first gate electrode and first gate spacers surrounding the first gate stack, and a plurality of second gate structures over the second active region each including a second gate stack having a second high-k gate dielectric and a second gate electrode and second gate spacers surrounding the second gate stack. At least a portion of the second gate electrode comprises dopants.

A semiconductor device structure, along with methods of forming such, are described. The structure includes a dielectric feature comprising a first dielectric layer and a second dielectric layer, the first dielectric layer has a first sidewall and a second sidewall opposing the first sidewall, and the second dielectric layer is in contact with at least a portion of the first sidewall and at least a portion of the second sidewall. The structure also includes a first semiconductor layer adjacent the first sidewall, wherein the first semiconductor layer is in contact with the second dielectric layer. The structure further includes a first gate electrode layer surrounding at least three surfaces of the first semiconductor layer, wherein the first gate electrode layer has a surface facing the second dielectric layer, and the surface extends over a plane defined by an interface between the second dielectric layer and the first semiconductor layer.

The present application provides a method for making gates of different sizes compatible with the double patterning technology, comprising: forming a plurality of dummy gate structures and spacers on the sidewalls; covering the spacers and a region of large-sized gates with an SOC(silicon-on-carbon) layer; etching the SOC layer to expose the spacers of at least one dummy gate structure; respectively forming the first and the second SOC pattern structures, wherein the first SOC pattern structure covers the spacer of at least one dummy gate structure, and the second SOC pattern structure is disposed in region of the large-sized gates; etching the first SOC pattern structure to form a third SOC pattern structure, one side of the third SOC pattern structure covers one side of the spacer, wherein the other uncovered side of the spacer is used to define one side of the gate of medium-sized width.

A semiconductor device includes a semiconductor substrate. The semiconductor device includes a first three-dimensional semiconductor structure of a first conductivity type protruding from a surface of the semiconductor substrate. The semiconductor device includes a second three-dimensional semiconductor structure of a second conductivity type protruding from the surface of the semiconductor substrate. The semiconductor device includes a first transistor having a first source/drain structure formed in the first three-dimensional semiconductor structure, a second source/drain structure formed in the second three-dimensional semiconductor structure, a first gate structure straddling a first portion of the first three-dimensional semiconductor structure and a first portion of the second three-dimensional semiconductor structure, and a second gate structure straddling a second portion of the second three-dimensional semiconductor structure.

A structure includes a first dielectric feature extending along a first direction, the first dielectric feature having a first side and a second side opposing the first side. The structure includes a first semiconductor layer disposed adjacent the first side of the first dielectric feature, the first semiconductor layer extending along a second direction perpendicular to the first direction. The structure includes a CESL in contact with the first dielectric feature and a portion of the first semiconductor layer, an ILD layer in contact with the CESL and a portion of the first semiconductor layer. The structure further includes a second dielectric feature extending along the first direction, the second dielectric feature comprising a first dielectric layer in contact with the CESL and a portion of the first semiconductor layer, and a second dielectric layer in contact with the first dielectric layer and a portion of the first semiconductor layer.

A method includes providing a structure having source/drain electrodes and a first dielectric layer over the source/drain electrodes; forming a first etch mask covering a first area of the first dielectric layer; performing a first etching process to the first dielectric layer, resulting in first trenches over the source/drain electrodes; filling the first trenches with a second dielectric layer that has a different material than the first dielectric layer; removing the first etch mask; performing a second etching process including isotropic etching to the first area of the first dielectric layer, resulting in a second trench above a first one of the source/drain electrodes; depositing a metal layer into at least the second trench; and performing a chemical mechanical planarization (CMP) process to the metal layer.

A device includes a substrate, a first semiconductor fin over the substrate extending in a first lateral direction, a first vertical stack of semiconductor nanosheets over the substrate extending in the first lateral direction, and an inactive fin between the first semiconductor fin and the first vertical stack extending in the first lateral direction. A first gate structure surrounds and covers the first semiconductor fin, and extends in a second lateral direction substantially perpendicular to the first lateral direction. A second gate structure surrounds and covers the first vertical stack, and extends in the second lateral direction.

A stacked FET structure having independently tuned gate lengths is provided to maximize the benefit of each FET within the stacked FET structure. Notably, a vertically stacked FET structure is provided in which a bottom FET has a different gate length than a top FET. In some embodiments, a dielectric spacer can be present laterally adjacent to the bottom FET and the top FET. In such an embodiment, the dielectric spacer can have a first portion that is located laterally adjacent to the bottom FET that has a different thickness than a second portion of the dielectric spacer that is located laterally adjacent the top FET.