A semiconductor device structure and a formation method are provided. The method includes forming a sacrificial base layer over a substrate and forming a semiconductor stack over the sacrificial base layer. The semiconductor stack has multiple sacrificial layers and multiple semiconductor layers laid out alternately. The method also includes forming a gate stack to partially cover the sacrificial base layer, the semiconductor layers, and the sacrificial layers. The method further includes removing the sacrificial base layer to form a recess between the substrate and the semiconductor stack. In addition, the method includes forming a metal-containing dielectric structure to partially or completely fill the recess. The metal-containing dielectric structure has multiple sub-layers.

Gate-all-around integrated circuit structures having a doped subfin, and methods of fabricating gate-all-around integrated circuit structures having a doped subfin, are described. For example, an integrated circuit structure includes a subfin structure having well dopants. A vertical arrangement of horizontal semiconductor nanowires is over the subfin structure. A gate stack is surrounding a channel region of the vertical arrangement of horizontal semiconductor nanowires, the gate stack overlying the subfin structure. A pair of epitaxial source or drain structures is at first and second ends of the vertical arrangement of horizontal semiconductor nanowires.

A semiconductor memory device includes: a substrate having first and second channel structures extending in a first direction arranged spaced apart in a second direction; a first gate structure disposed on the first channel structure; a second gate structure disposed on the second channel structure; first source/drain regions disposed on opposite sides of the first gate structure; second source/drain regions disposed on opposite sides of the second gate structure; a gate separation pattern disposed between the gate structures to directly contact the gate structures and having an upper surface disposed at a level lower than an upper surface of the gate structures along a third direction; and a gate capping layer disposed on the gate structures and having an extension portion disposed between the gate structures such that the extension portion directly contacts the gate structures, the gate capping layer being connected to the gate separation pattern.

In some embodiments, a method includes forming a plurality of nanostructures over a substrate; etching the plurality of nanostructures to form first recesses; forming source/drain regions in the first recesses; removing first nanostructures of the plurality of nanostructures leaving second nanostructures of the plurality of nanostructures; depositing a gate dielectric over and around the second nanostructures; performing an aluminum treatment on the gate dielectric; depositing a first conductive material over and around the gate dielectric; performing a fluorine treatment on the first conductive material; and depositing a second conductive material over and around the first conductive material.

An integrated circuit (IC) device includes a front-side interconnect layer, a transistor device, a dielectric layer, a memory structure, and a backside interconnect layer. The transistor device has a gate structure over the front-side interconnect layer. The dielectric layer is over the transistor device. The memory structure is over the dielectric layer. The backside interconnect layer is over the memory structure.

A semiconductor device includes a plurality of active regions on a substrate. A gate electrode is on, and intersects, the active regions. A plurality of source/drain regions are on the active regions, such that the source/drain regions are adjacent to opposite sides of the gate electrode and the gate electrode is between the source/drain regions. A separation structure is between adjacent source/drain regions. The separation structure includes an insulating pattern and a spacer layer. The insulating pattern includes first and second side surfaces that are opposite side surfaces of the insulating pattern and are adjacent to separate, respective source/drain regions. The spacer layer is on the first and second side surfaces. An uppermost end of the insulating pattern is farther from a lower surface of the substrate than a first upper surface of the spacer layer that is adjacent to the first and second side surfaces.

A semiconductor device structure, along with methods of forming such, are described. The structure includes a first source/drain region, a second source/drain region adjacent the first source/drain region, an interlayer dielectric layer disposed between the first source/drain region and the second source/drain region, and a conductive feature disposed in the interlayer dielectric layer between the first source/drain region and the second source/drain region. The conductive feature includes a first portion and a second portion extending from the first portion, and an angle is formed between the first portion and the second portion. The angle is less than about 180 degrees. The conductive feature is electrically connected to the first source/drain region.

Integrated circuits including lateral diodes. In an example, diodes are formed with laterally neighboring source and drain regions (diffusion regions) configured with different polarity epitaxial growths (e.g., p-type and n-type), to provide an anode and cathode of the diode. In some such cases, dopants may be used in the channel region to create or otherwise enhance a PN or PIN junction between the diffusion regions and the semiconductor material of a channel region. The channel region can be, for instance, one or more nanoribbons or other such semiconductor bodies that extend between the oppositely-doped diffusion regions. In some cases, nanoribbons making up the channel region are left unreleased, thereby preserving greater volume through which diode current can flow. Other features include skipped epitaxial regions, elongated gate structures, using isolation structures in place of gate structures, and/or sub-fin conduction paths that are supplemental or alternative to a channel-based conduction path.

A FET channel includes a stack of silicon nanosheets. The silicon nanosheets are oriented parallel to a planar portion of the FET in which the FET channel is formed. The FET channel also includes a vertical blocker fin. The vertical blocker fin is attached to at least one nanosheet in the stack of nanosheets.

A semiconductor device includes; an active pattern on a substrate, a source/drain pattern on the active pattern, a channel pattern connected to the source/drain pattern and including semiconductor patterns spaced apart in a vertical stack, and a gate electrode extending across the channel pattern. The semiconductor patterns includes a first semiconductor pattern and a second semiconductor pattern. The gate electrode includes a first part between the substrate and the first semiconductor pattern and a second part between the first semiconductor pattern and the second semiconductor pattern. A width of the first part varies with a depth of the first part, such that a width of a middle portion of the first part is less than a width of a lower portion of the first part and a width of an upper portion of the first part.