A device includes a semiconductor substrate and a first gate stack over the semiconductor substrate, the first gate stack being between a first gate spacer and a second gate spacer. The device further includes a second gate stack over the semiconductor substrate between the first gate spacer and the second gate spacer and a dielectric material separating the first gate stack from the second gate stack. The dielectric material is at least partially between the first gate spacer and the second gate spacer, a first width of an upper portion of the dielectric material is greater than a second width of a lower portion of the dielectric material, and a third width of an upper portion of the first gate spacer is less than a fourth width of a lower portion of the first gate spacer.

A method of forming a semiconductor device includes etching a substrate to form two first trenches separated by a fin; filling the two first trenches with an isolation layer; and depositing a dielectric layer over the fin and the isolation layer. The method further includes forming a second trench in the dielectric layer over a channel region of the semiconductor device, the second trench exposing the isolation layer. The method further includes etching the isolation layer through the second trench to expose an upper portion of the fin in the channel region of the semiconductor device, and forming a dummy gate in the second trench over the isolation layer and engaging the upper portion of the fin.

An integrated circuit structure comprises a semiconductor fin protruding through a trench isolation region above a substrate. A gate structure is over the semiconductor fin. A plurality of vertically stacked nanowires is through the gate structure, wherein the plurality of vertically stacked nanowires includes a top nanowire adjacent to a top of the gate structure, and a bottom nanowire adjacent to a top of the semiconductor fin. A dielectric material covers only a portion of the plurality of vertically stacked nanowires outside the gate structure, such that one or more one of the plurality of vertically stacked nanowires starting with the top nanowire is exposed from the dielectric material. Source and drain regions are on opposite sides of the gate structure connected to the exposed ones of the plurality of vertically stacked nanowires.

Processing methods may be performed to form an airgap in a semiconductor structure. The methods may include forming a high-k material on a floor of a trench. The trench may be defined on a semiconductor substrate between sidewalls of a first material and a spacer material. The methods may include forming a gate structure on the high-k material. The gate structure may contact the first material along each sidewall of the trench. The methods may also include etching the first material. The etching may form an airgap adjacent the gate structure.

An integrated circuit device includes a plurality of metal gates each having a metal electrode and a high-κ dielectric and a plurality of polysilicon gates each having a polysilicon electrode and conventional (non high-κ) dielectrics. The polysilicon gates may have adaptations for operation as high voltage gates including thick dielectric layers and area greater than one μm.sup.2. Polysilicon gates with these adaptations may be operative with gate voltages of 10V or higher and may be used in embedded memory devices.

A semiconductor device includes a first semiconductor fin, a first epitaxial layer, a first alloy layer and a contact plug. The first semiconductor fin is on a substrate. The first epitaxial layer is on the first semiconductor fin. The first alloy layer is on the first epitaxial layer. The first alloy layer is made of one or more Group IV elements and one or more metal elements, and the first alloy layer comprises a first sidewall and a second sidewall extending downwardly from a bottom of the first sidewall along a direction non-parallel to the first sidewall. The contact plug is in contact with the first and second sidewalls of the first alloy layer.

Semiconductor devices include a channel fin having a top surface. A top semiconductor structure, in contact with the entire top surface of the channel fin and having a top portion and a bottom portion, with the top portion of the top semiconductor structure being narrower than the bottom portion. A restraint structure being formed over the bottom portion of the semiconductor structure.

The present disclosure provides semiconductor devices and methods of forming the same. A semiconductor device of the present disclosure includes a first source/drain feature and a second source/drain feature over a substrate, a plurality of channel members extending between the first source/drain feature and the second source/drain feature, a gate structure wrapping around each of the plurality of channel members, and at least one blocking feature. At least one of the plurality of channel members is isolated from the first source/drain feature and the second source/drain feature by the at least one blocking feature.

A semiconductor device structure, along with methods of forming such, are described. The structure includes a substrate, a source/drain contact disposed over the substrate, a first dielectric layer disposed on the source drain contact, an etch stop layer disposed on the first dielectric layer, and a source/drain conductive layer disposed in the etch stop layer and the first dielectric layer. The structure further includes a spacer structure disposed in the etch stop layer and the first dielectric layer. The spacer structure surrounds a sidewall of the source/drain conductive layer and includes a first spacer layer having a first portion and a second spacer layer adjacent the first portion of the first spacer layer. The first portion of the first spacer layer and the second spacer layer are separated by an air gap. The structure further includes a seal layer.

Semiconductor device structures having dielectric features and methods of forming dielectric features are described herein. In some examples, the dielectric features are formed by an ALD process followed by a varying temperature anneal process. The dielectric features can have high density, low carbon concentration, and lower k-value. The dielectric features formed according to the present disclosure has improved resistance against etching chemistry, plasma damage, and physical bombardment in subsequent processes while maintaining a lower k-value for target capacitance efficiency.