Abstract: Semiconductor devices including fin-shaped isolation structures and methods of forming the same are disclosed. In an embodiment, a semiconductor device includes a fin extending from a semiconductor substrate; a shallow trench isolation (STI) region over the semiconductor substrate adjacent the fin; and a dielectric fin structure over the STI region, the dielectric fin structure extending in a direction parallel to the fin, the dielectric fin structure including a first liner layer in contact with the STI region; and a first fill material over the first liner layer, the first fill material including a seam disposed in a lower portion of the first fill material and separated from a top surface of the first fill material, a first carbon concentration in the lower portion of the first fill material being greater than a second carbon concentration in an upper portion of the first fill material.

Abstract: The present disclosure describes forming a semiconductor structure having an isolation layer surrounding a portion of a gate structure. The semiconductor structure includes a channel structure on a substrate, a first isolation layer on the substrate and surrounding the channel structure, and a gate structure on the channel structure and the first isolation layer. The gate structure includes a first portion having a first width and a second portion having a second width less than the first width. The semiconductor structure further includes a second isolation layer on the first isolation layer and surrounding the first portion of the gate structure.

Abstract: A dummy gate structure is formed over a plurality of active regions. The dummy gate structure extends in a first horizontal direction in a planar top view. The active regions each extend in a second horizontal direction in the planar top view. The second horizontal direction is different from the first horizontal direction. A plurality of source/drain components is formed over the active regions. A dielectric structure is formed over the source/drain components. The dummy gate structure is then removed. A removal of the dummy gate structure exposes a first segment of each of the active regions. A thickness of the first segment of each of the active regions is reduced in the first horizontal direction.

Abstract: The present disclosure describes forming a semiconductor structure having an isolation layer surrounding a sloped portion of a channel structure. The semiconductor structure includes a channel structure having first, second, and third portions on a substrate. The first portion has a first width. The second portion has a second width less than the first width. The third portion has a third width less than the second width. The semiconductor structure further includes a first isolation layer on the substrate and surrounding the first portion, a second isolation layer on the first isolation layer and surrounding the second portion of the channel structure, and a gate structure on the second isolation layer and surrounding the third portion of the channel structure.

Abstract: Noise semiconductor devices and methods of forming the same are provided. A semiconductor device according to the present disclosure includes a substrate, a fin structure over the substrate and extending lengthwise along a direction, the fin structure including a middle section sandwiched between a first end section and a second section along the direction, a gate structure wrapping over a channel region of the middle section, and a first source/drain feature and a second source/drain feature sandwiching the channel region of the middle section along the direction, The middle section includes a first semiconductor material and the first end section and the second end section include a second semiconductor material different from the first semiconductor material.

Abstract: A semiconductor device includes a substrate and a device. The substrate has a first surface and a second surface opposite to each other. The substrate includes a first well region, and the first well region includes a first shallow implantation region adjacent to the first surface and a first deep implantation region adjacent to the second surface, in which a dopant concentration of the first deep implantation region at the second surface is substantially equal to 0. The device is disposed on the first surface of the substrate and adjoins the first shallow implantation region.

Abstract: An image sensor and a fabrication method thereof are provided. In the fabrication method of the image sensor, at first, two isolation features are formed in a substrate to define a pixel region. Then, a floating node and a pinning layer are formed in one of the isolation features, in which a space region is located between the floating node and the pinning layer, and the floating node has a first conductivity type different from a second conductivity type of the pinning layer. Thereafter, a light-sensitive element is formed in the pixel region, and a transfer gate is formed on the pixel region, thereby forming a pixel. Since there is a space region located between the floating node and the pinning layer, a leakage path between the floating node and the pinning layer can be prevented.

Abstract: A semiconductor device includes a substrate and a device. The substrate has a first surface and a second surface opposite to each other. The substrate includes a first well region, and the first well region includes a first shallow implantation region adjacent to the first surface and a first deep implantation region adjacent to the second surface, in which a dopant concentration of the first deep implantation region at the second surface is substantially equal to 0. The device is disposed on the first surface of the substrate and adjoins the first shallow implantation region.

Abstract: An image sensor and a fabrication method thereof are provided. In the fabrication method of the image sensor, at first, two isolation features are formed in a substrate to define a pixel region. Then, a floating node and a pinning layer are formed in one of the isolation features, in which a space region is located between the floating node and the pinning layer, and the floating node has a first conductivity type different from a second conductivity type of the pinning layer. Thereafter, a light-sensitive element is formed in the pixel region, and a transfer gate is formed on the pixel region, thereby forming a pixel. Since there is a space region located between the floating node and the pinning layer, a leakage path between the floating node and the pinning layer can be prevented.