A semiconductor memory device includes a semiconductor substrate, a select gate on the semiconductor substrate, a control gate disposed adjacent to the select gate and having a first sidewall and a second sidewall, and a charge storage layer between the control gate and the semiconductor substrate. The control gate includes a third sidewall close to the second sidewall of the select gate, a fourth sidewall opposite to the third sidewall, and a non-planar top surface between the third sidewall and the fourth sidewall. The non-planar top surface includes a first surface region that descends from the third sidewall to the fourth sidewall. The charge storage layer extends to the second sidewall of the select gate.

A variety of applications can include memory devices designed to provide enhanced gate-induced-drain-leakage (GIDL) current during memory erase operations. The enhanced operation can be provided by enhancing the electric field in the channel structures of select gate transistors to strings of memory cells. The channel structures can be implemented as a segmented portion for drains and a portion opposite a gate. The segmented portion includes one or more fins and one or more non-conductive regions with both fins and non-conductive regions extending vertically from the portion opposite the gate. Variations of a border region for the portion opposite the gate with the segmented portion can include fanged regions extending from the fins into the portion opposite the gate or rounded border regions below the non-conductive regions. Such select gate transistors can be formed using a single photo mask process. Additional devices, systems, and methods are discussed.

A semiconductor device is provided that includes a local passthrough interconnect structure present in a non-active device region of the device. A dielectric fill material structure is located between the local passthrough interconnect structure and a functional gate structure that is present in an active device region that is laterally adjacent to the non-active device region. The semiconductor device has reduced capacitance (and thus circuit speed is not compromised) as compared to an equivalent device in which a metal-containing sacrificial gate structure is used instead of the dielectric fill material structure.

A finFET device and methods of forming a finFET device are provided. The device includes a fin and a capping layer over the fin. The device also includes a gate stack over the fin, the gate stack including a gate electrode and a gate dielectric. The gate dielectric extends along sidewalls of the capping layer. The device further includes a gate spacer adjacent to sidewalls of the gate electrode, the capping layer being interposed between the gate spacer and the fin.

Devices and structures that include a gate spacer having a gap or void are described along with methods of forming such devices and structures. In accordance with some embodiments, a structure includes a substrate, a gate stack over the substrate, a contact over the substrate, and a spacer disposed laterally between the gate stack and the contact. The spacer includes a first dielectric sidewall portion and a second dielectric sidewall portion. A void is disposed between the first dielectric sidewall portion and the second dielectric sidewall portion.

An integrated circuit structure includes a semiconductor substrate; insulation regions over the semiconductor substrate; and an epitaxy region over the semiconductor substrate and having at least a portion in a space between the insulation regions. The epitaxy region includes a III-V compound semiconductor material. The epitaxy region also includes a lower portion and an upper portion over the lower portion. The lower portion and the semiconductor substrate have a first lattice mismatch. The upper portion and the semiconductor substrate have a second lattice mismatch different from the first lattice mismatch.

Technologies for selectively etching oxide and nitride materials on a work piece are described. Such technologies include methods for etching a work piece with a remote plasma that is produced by igniting a plasma gas flow. By controlling the flow rate of various components of the plasma gas flow, plasmas exhibiting desired etching characteristics may be obtained. Such plasmas may be used in single or multistep etching operations, such as recess etching operations that may be used in the production of non-planar microelectronic devices.

A semiconductor device with reinforced gate spacers and a method of fabricating the same. The semiconductor device includes low-k dielectric gate spacers adjacent to a gate structure. A high-k dielectric material is disposed over an upper surface of the low-k dielectric gate spacers to prevent unnecessary contact between the gate structure and a self-aligned contact structure. The high-k dielectric material may be disposed, if desired, over an upper surface of the gate structure to provide additional isolation of the gate structure from the self-aligned contact structure.

The present disclosure is directed to a semiconductor device and a manufacturing method thereof, which relate to the field of semiconductor technologies. The semiconductor device includes a fin ESD element. The method includes: providing a substrate structure, where the substrate structure includes a semiconductor substrate, and a semiconductor fin for the fin ESD element and an electrode structure surrounding a part of the semiconductor fin that are on the semiconductor substrate; forming a second dielectric layer on the substrate structure to cover the electrode structure; forming, in the second dielectric layer, a trench extending to a top of the electrode, where the trench is on the electrode and extends along a longitudinal direction of the electrode, and a transverse width of the trench is less than or equal to a transverse width of the top of the electrode; and filling the trench with a metal material, so as to form a metal heat sink that is on the top of the electrode and is coupled to the electrode. With the present disclosure, an existing structure of an ESD element is improved, so that a metal heat sink can effectively improve a head dissipation effect of a device, thereby improving a performance of the device.

A varactor transistor includes a semiconductor fin having a first conductivity type, a plurality of gate structures separated from each other and surrounding a portion of the semiconductor fin. The plurality of gates structures include a dummy gate structure on an edge of the semiconductor fin, and a first gate structure spaced apart from the dummy gate structure. The dummy gate structure and the gate structure each include a gate insulator layer on a surface portion of the semiconductor fin, a gate on the gate insulator layer, and a spacer on the gate. The varactor transistor also includes a raised source/drain region on the semiconductor fin and between the dummy gate structure and the first gate structure, the raised source/drain region and the gate of the dummy gate structure being electrically connected to a same potential.