A semiconductor structure includes a substrate with a conductive structure thereon, a first dielectric layer, a conductive feature and a second dielectric layer. The substrate includes a conductive feature. The conductive feature is formed in the first dielectric layer, is electrically connected to the conductive feature. The second dielectric layer is formed on the first dielectric layer and is disposed adjacent to the conductive feature. The first dielectric layer and the second dielectric layer are made of different materials.

A method for manufacturing a memory includes: providing a substrate having a core region provided with a word line; forming a dielectric layer on the substrate, and etching the dielectric layer to form a first filling hole exposing the word line; forming a barrier layer on a hole wall of the first filling hole, where the barrier layer located in the first filling hole surrounds and forms a first intermediate hole exposing the word line; etching the word line exposed in the first intermediate hole to remove a first residue on the word line; and forming in the first intermediate hole a first wire electrically connected to the word line.

In a method of manufacturing a semiconductor device, a source/drain structure is formed over a substrate, a first interlayer dielectric (ILD) layer including one or more dielectric layers is formed over the source/drain structure, a first opening is formed in the first ILD layer to at least partially expose the source/drain structure, a sacrificial layer is formed on an inner wall of the first opening, a first insulating layer is formed on the sacrificial layer, a conductive layer is formed on the first insulating layer so as to form a source/drain contact in contact with the source/drain structure, the sacrificial layer is removed to form a space between the first insulating layer and the first ILD layer, and a second insulating layer is formed over the source/drain contact and the first ILD layer to cap an upper opening of the space, thereby forming an air gap.

A semiconductor device includes: a first conductive structure having sidewalls and a bottom surface, the first conductive structure extending through one or more isolation layers formed on a substrate; and an insulation layer disposed between at least one of the sidewalls of the first conductive structure and respective sidewalls of the one or more isolation layers, wherein the first conductive structure is electrically coupled to a second conductive structure through at least the bottom surface.

In one exemplary aspect, a method comprises providing a semiconductor structure having a substrate, one or more first dielectric layers over the substrate, a first metal plug in the one or more first dielectric layers, and one or more second dielectric layers over the one or more first dielectric layers and the first metal plug. The method further comprises etching a via hole into the one or more second dielectric layers to expose the first metal plug, etching a top surface of the first metal plug to create a recess thereon, and applying a metal corrosion protectant comprising a metal corrosion inhibitor to the top surface of the first metal plug.

A method of fabricating a semiconductor structure and the semiconductor structure are disclosed. The method uses high flow rate of an etchant and an optimized scan pattern, so that the obtained semiconductor structure is a device upside-down bonded to the carrier wafer without any silicon remaining and is ready for subsequent lithography process for back via contact.

A semiconductor device and method of manufacture are provided. A source/drain region is formed next to a spacer, which is adjacent to a gate electrode. An implantation is performed through an implantation mask into the source/drain region as well as the first spacer, forming an implantation region within the spacer.

The present disclosure describes semiconductor devices and methods for forming the same. A method for forming a semiconductor device includes forming a source/drain structure and forming a gate structure. The method also includes performing a cleaning process on the source/drain structure and the gate structure. The method also includes disposing a portion of a byproduct of the cleaning process on a top surface of the gate structure and etching the portion of the byproduct so a remaining portion of the byproduct is formed on the top surface of the gate structure. The method further includes forming a gate contact structure, including depositing a metal material on the remaining portion of the byproduct to form a compound containing the metal material and the remaining portion of the byproduct. The method also includes forming a barrier layer between the compound and the top surface of the gate structure.

The present disclosure provides an integrated circuit (IC) structure. The IC structure includes a semiconductor substrate; an interconnection structure formed on the semiconductor substrate; and a redistribution layer (RDL) metallic feature formed on the interconnection structure. The RDL metallic feature further includes a barrier layer disposed on the interconnection structure; a diffusion layer disposed on the barrier layer, wherein the diffusion layer includes metal and oxygen; and a metallic layer disposed on the diffusion layer.

In some implementations, fluorine is oxidized after dry etching an oxide layer above a source/drain contact and before cleaning. Accordingly, less hydrofluoric acid is formed during cleaning, which reduces unexpected wet etching of the source/drain contact. This allows for forming a recess in the source/drain contact with a depth to width ratio in a range from approximately 1.0 to approximately 1.4 and prevents damage to a layer of silicide below the source/drain that can be caused by excessive hydrofluoric acid. Additionally, or alternatively, the recess is formed using multiple wet etch processes, and any residual fluorine is oxidized between the wet etch processes. Accordingly, each wet etching process may be shorter and less corrosive, which allows for greater control over dimensions of the recess. Additionally, less hydrofluoric acid may be formed during cleaning processes between the wet etch processes, which reduces the etching of the source/drain contact between processes.