In an embodiment, a device includes: an isolation region on a substrate; a fin structure protruding from between adjacent portions of the isolation region, the fin structure including a plurality of fins and a mesa, a channel region of the fin structure having a first portion in the fins and having a second portion in the mesa, the fins and the mesa being a continuous semiconductor material, the mesa having a greater width than the fins; and a first gate structure on the fin structure, the first gate structure extending along the first portion of the channel region in the fins and extending along the second portion of the channel region in the mesa.

Semiconductor structures and methods of forming the same are provided. A semiconductor structure according to the present disclosure includes at least one first semiconductor element and at least one second semiconductor element over a substrate, a dielectric fin disposed between the at least one first semiconductor element and the at least one second semiconductor element, a first work function metal layer wrapping around each of the at least one first semiconductor element and extending continuously from the at least one first semiconductor element to a top surface of the dielectric fin, and a second work function metal layer disposed over the at least one second semiconductor element and the first work function metal layer.

A method of manufacturing a semiconductor device includes forming an active fin protruding from a substrate and extending in a first direction; forming sacrificial gate patterns intersecting the active fin and extend in a second direction; forming recess regions by etching the active fin on at least one side of each of the sacrificial gate patterns; forming source/drain regions on the recess regions; removing the sacrificial gate patterns to form openings; and forming a gate dielectric layer and a gate electrode such that gate structures are formed to cover the active fin in the openings. The source/drain regions are formed by an epitaxial growth process and an in-situ doping process of doping first conductivity-type impurity elements. In at least one of the source/drain regions, after the in-situ doping process is performed, counter-doping is performed using second conductivity-type impurity elements different from the first conductivity-type impurity elements to decrease carrier concentration.

A method includes depositing a multi-layer stack on a semiconductor substrate, the multi-layer stack including a plurality of sacrificial layers that alternate with a plurality of channel layers; forming a dummy gate on the multi-layer stack; forming a first spacer on a sidewall of the dummy gate; performing a first implantation process to form a first doped region, the first implantation process having a first implant energy and a first implant dose; performing a second implantation process to form a second doped region, where the first doped region and the second doped region are in a portion of the channel layers uncovered by the first spacer and the dummy gate, the second implantation process having a second implant energy and a second implant dose, where the second implant energy is greater than the first implant energy, and where the first implant dose is different from the second implant dose.

A transistor with a high on-state current and a semiconductor device with high productivity are provided. Included are a first oxide, a second oxide, a third oxide, and a fourth oxide over a first insulator; a first conductor over the third oxide; a second conductor over the fourth oxide; a second insulator over the first conductor; a third insulator over the second conductor; a fifth oxide positioned over the second oxide and between the third oxide and the fourth oxide; a sixth oxide over the fifth oxide; a fourth insulator over the sixth oxide; a third conductor over the fourth insulator; and a fifth insulator over the first insulator to the third insulator. The fifth oxide includes a region in contact with the second oxide to the fourth oxide and the first insulator. The sixth oxide includes a region in contact with the fifth oxide, the first conductor, and the second conductor. The fourth insulator includes a region in contact with at least the sixth oxide, the third conductor, and the fifth insulator.

A semiconductor structure includes at least a fin structure, a gate structure over the fin structure, a connecting structure, a first dielectric structure over the gate structure, and a second dielectric structure. The fin structure extends in a first direction, and the gate structure extends in a second direction different from the first direction. The connecting structure is disposed over the fin structure and isolated from the gate structure. The second dielectric structure extends in the first direction. The first dielectric structure and the second dielectric structure include a same material. A top surface of the first dielectric structure and a top surface of the second dielectric structure are substantially aligned with each other.

The present disclosure provides a semiconductor structure. The semiconductor structure includes a fin active region formed on a semiconductor substrate and spanning between a first sidewall of a first shallow trench isolation (STI) feature and a second sidewall of a second STI feature; an anti-punch through (APT) feature of a first type conductivity; and a channel material layer of the first type conductivity, disposed on the APT feature and having a second doping concentration less than the first doping concentration. The APT feature is formed on the fin active region, spans between the first sidewall and the second sidewall, and has a first doping concentration.

A semiconductor device with multiple silicide regions is provided. In embodiments a first silicide precursor and a second silicide precursor are deposited on a source/drain region. A first silicide with a first phase is formed, and the second silicide precursor is insoluble within the first phase of the first silicide. The first phase of the first silicide is modified to a second phase of the first silicide, and the second silicide precursor being soluble within the second phase of the first silicide. A second silicide is formed with the second silicide precursor and the second phase of the first silicide.

The present disclosure provides an integrated circuit device that comprises a semiconductor substrate having a top surface; a first and a second source/drain features over the semiconductor substrate; a first semiconductor layer extending in parallel with the top surface and connecting the first and the second source/drain features, the first semiconductor layer having a center portion and two end portions, each of the two end portions connecting the center portion and one of the first and second source/drain features; a first spacer over the two end portions of the first semiconductor layer; a second spacer vertically between the two end portions of the first semiconductor layer and the top surface; and a gate electrode wrapping around and engaging the center portion of the first semiconductor layer. The center portion has a thickness smaller than the two end portions.

A semiconductor device including fin field-effect transistors, includes a first gate structure extending in a first direction, a second gate structure extending the first direction and aligned with the first gate structure in the first direction, a third gate structure extending in the first direction and arranged in parallel with the first gate structure in a second direction crossing the first direction, a fourth gate structure extending the first direction, aligned with the third gate structure and arranged in parallel with the second gate structure, an interlayer dielectric layer disposed between the first to fourth gate electrodes, and a separation wall made of different material than the interlayer dielectric layer and disposed between the first and third gate structures and the second and fourth gate structures.