An IC structure includes a first SRAM cell and a second SRAM, where a layout of the second SRAM cell is a mirror image of that of the first SRAM cell about a vertical cell boundary therebetween. The first SRAM cell includes a first PD device and a second PD device disposed over a first fin and a second fin, respectively, where a portion of the first fin and a portion of the second fin corresponding to a channel region of the first and the second PD devices, respectively, each include a first stack of semiconductor layers defined by a channel width W1, a portion of the first fin and a portion of the second fin providing a source terminal of the first and the second PD devices, respectively, are each defined by a width W1′ that is enlarged with respect to the channel width W1.

A structure includes a substrate, an isolation structure over the substrate, a fin extending from the substrate and adjacent to the isolation structure, two source/drain (S/D) features over the fin, channel layers suspended over the substrate and connecting the S/D features, a first gate structure wrapping around each of the channel layers in the stack, two outer spacers disposed on two opposing sidewalls of the first gate structure that are on outer surfaces of the stack, inner spacers disposed between the S/D features and the channel layers, and a gate-end dielectric feature over the isolation structure and directly contacting an end of the gate structure. The gate-end dielectric feature includes a first material of a dielectric constant that is higher than dielectric constants of materials included in the outer spacers and the inner spacers.

A method of forming a semiconductor transistor device. The method comprises forming a fin-shaped channel structure over a substrate and forming a first source/drain epitaxial structure and a second source/drain epitaxial structure on opposite endings of the fin structure. The method further comprises forming a metal gate structure surrounding the fin structure. The method further comprises flipping and partially removing the substrate to form a back-side capping trench while leaving a lower portion of the substrate along upper sidewalls of the first source/drain epitaxial structure and the second source/drain epitaxial structure as a protective spacer. The method further comprises forming a back-side dielectric cap in the back-side capping trench.

A semiconductor device structure, along with methods of forming such, are described. The structure includes a plurality of semiconductor layers and a first source/drain epitaxial feature in contact with the plurality of semiconductor layers. The first source/drain epitaxial feature includes a bottom portion having substantially straight sidewalls. The structure further includes a spacer having a gate spacer portion and one or more source/drain spacer portions. Each source/drain spacer portion has a first height, and a source/drain spacer portion of the one or more source/drain spacer portions is in contact with one of the substantially straight sidewalls of the first source/drain epitaxial feature. The structure further includes a dielectric feature disposed adjacent one source/drain spacer portion of the one or more source/drain spacer portion. The dielectric has a second height substantially greater than the first height.

In a method for forming a semiconductor device, a layer of logic devices is formed on a substrate. The layer of logic devices includes a stack of gate-all-around field-effect transistors (GAA-FETs) positioned over the substrate, where the stack of GAA-FETs includes a first layer of GAA-FETs stacked over a second layer of GAA-FETs. A first wiring layer is formed over the layer of logic devices, where the first wiring layer includes one or more metal routing levels. A memory stack is formed over the first wiring layer. The memory stack includes wordline layers and insulating layers that alternatingly arranged over the first wiring layer. A three-dimensional (3D) NAND memory device is formed in the memory stack. The 3D NAND memory device includes a channel structure that extends into the memory stack and further is coupled to the wordline layers of the memory stack.

A method includes forming a p-well and an n-well in a substrate. The method further includes forming a stack of interleaving first semiconductor layers and second semiconductor layers over the p-well and the n-well, the first semiconductor layers having a first thickness and the second semiconductor layers having a second thickness different than the first thickness. The method further includes annealing the stack of interleaving semiconductor layers. The method further includes patterning the stack to form fin-shaped structures including a first fin-shaped structure over the n-well and a second fin-shaped structure over the p-well. The method further includes etching to remove the second semiconductor layers from the first and second fin-shaped structures, where the first semiconductor layers have a different thickness within each of the first and second fin-shaped structures after the etching. The method further includes forming a metal gate over the first and second fin-shaped structures.

A semiconductor device includes a semiconductor substrate, a plurality of semiconductor fins, a gate stack and an epitaxy structure. The semiconductor fins are present on the semiconductor substrate. The semiconductor fins respectively include recesses therein. The gate stack is present on portions of the semiconductor fins that are adjacent to the recesses. The epitaxy structure is present across the recesses of the semiconductor fins. The epitaxy structure includes a plurality of corners and at least one groove present between the corners, and the groove has a curvature radius greater than that of at least one of the corners.

Semiconductor devices are provided. The semiconductor devices may include a first wire pattern extending in a first direction on a substrate and a second wire pattern on the first wire pattern. The second wire pattern may be spaced apart from the first wire pattern and extends in the first direction. The semiconductor devices may also include a first gate structure at least partially surrounding the first wire pattern and the second wire pattern, a second gate structure spaced apart from the first gate structure in the first direction, a first source/drain region between the first gate structure and the second gate structure, a first spacer between a bottom surface of the first source/drain region and the substrate, a first source/drain contact on the first source/drain region, and a second spacer between the first source/drain contact and the first gate structure.

A method of forming a vertical fin field effect transistor (vertical finFET) with an increased surface area between a source/drain contact and a doped region, including forming a doped region on a substrate, forming one or more interfacial features on the doped region, and forming a source/drain contact on at least a portion of the doped region, wherein the one or more interfacial features increases the surface area of the interface between the source/drain contact and the doped region compared to a flat source/drain contact-doped region interface.

The present disclosure provides methods for forming conductive features in a dielectric layer without using adhesion layers or barrier layers and devices formed thereby. In some embodiments, a structure comprising a dielectric layer over a substrate, and a conductive feature disposed through the dielectric layer. The dielectric layer has a lower surface near the substrate and a top surface distal from the substrate. The conductive feature is in direct contact with the dielectric layer, and the dielectric layer comprises an implant species. A concentration of the implant species in the dielectric layer has a peak concentration proximate the top surface of the dielectric layer, and the concentration of the implant species decreases from the peak concentration in a direction towards the lower surface of the dielectric layer.