The present disclosure describes a semiconductor device that includes nanostructures on a substrate and a source/drain region in contact with the nanostructures. The source/drain region includes (i) a first epitaxial structure embedded in the substrate; (ii) a nitride layer on the first epitaxial structure; and a second epitaxial structure on the first epitaxial structure. The semiconductor device also includes a gate structure formed on the nanostructures.

Embodiments of the disclosure provide an improved apparatus and methods for nitridation of stacks of materials. In one embodiment, a method for processing a substrate in a processing region of a process chamber is provided. The method includes generating and flowing plasma species from a remote plasma source to a delivery member having a longitudinal passageway, flowing plasma species from the longitudinal passageway to an inlet port formed in a sidewall of the process chamber, wherein the plasma species are flowed at an angle into the inlet port to promote collision of ions or reaction of ions with electrons or charged particles in the plasma species such that ions are substantially eliminated from the plasma species before entering the processing region of the process chamber, and selectively incorporating atomic radicals from the plasma species in silicon or polysilicon regions of the substrate.

The invention provides a fin structure for a fin field effect transistor, including a substrate. The substrate includes a plurality of silicon fins, wherein a top of each one of the silicon fins is a round-like shape in a cross-section view. An isolation layer is disposed on the substrate between the silicon fins at a lower portion of the silicon fins while an upper portion of the silicon fins is exposed. A stress buffer layer is disposed on a sidewall of the silicon fins between the isolation layer and the lower portion of the silicon fins. The stress buffer layer includes a nitride portion.

The present disclosure relates to a semiconductor structure and a manufacturing method thereof. The manufacturing method of a semiconductor structure includes: providing a substrate, where a plurality of contact pads are formed on the substrate; depositing a dielectric layer on the substrate, where the dielectric layer fills gaps between the contact pads and covers the contact pads; and etching the dielectric layer through a plasma etching process to expose the contact pads, where an etching gas used in the plasma etching process includes an oxygen-free etching gas. The manufacturing method can avoid the formation of metal oxides on the contact pads, and avoid residual conductive metal particles or metal compounds on surfaces of the contact pads and the adjacent dielectric layers, which is beneficial to ensure the electrical performance of the semiconductor structure, thereby improving the use reliability of the semiconductor structure.

A method of manufacturing a semiconductor device, includes forming a sacrificial film made of a polymer having a urea bond on a substrate by supplying an amine and an isocyanate to a surface of the substrate, wherein the sacrificial film is provided in a specific region of the substrate; performing a predetermined process on the substrate on which the sacrificial film is formed; and removing the sacrificial film by heating the substrate to depolymerize the polymer, wherein a carbon bonded to a nitrogen atom contained in an isocyanate group of the isocyanate is a secondary or tertiary non-aromatic carbon.

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.

The present disclosure describes a method for forming a nitrogen-rich protective layer within a low-k layer of a metallization layer to prevent damage to the low-k layer from subsequent processing operations. The method includes forming, on a substrate, a metallization layer having conductive structures in a low-k dielectric. The method further includes forming a capping layer on the conductive structures, where forming the capping layer includes exposing the metallization layer to a first plasma process to form a nitrogen-rich protective layer below a top surface of the low-k dielectric, releasing a precursor on the metallization layer to cover top surfaces of the conductive structures with precursor molecules, and treating the precursor molecules with a second plasma process to dissociate the precursor molecules and form the capping layer. Additionally, the method includes forming an etch stop layer to cover the capping layer and top surfaces of the low-k dielectric.

A method for manufacturing a semiconductor structure includes: a substrate is provided; the substrate is etched to form a blind hole, a sidewall of the blind hole has a first roughness; at least one planarization process is performed on the sidewall of the blind hole until the sidewall of the blind hole has a preset roughness less than the first roughness. The planarization process includes: a first sacrificial layer is formed on the sidewall of the blind hole; a reaction source gas is provided such that the reaction source gas reacts with the first sacrificial layer and a portion of the substrate at the sidewall of the blind hole to form a second sacrificial layer; and the second sacrificial layer is removed, and after the second sacrificial layer is removed, the sidewall of the blind hole has a second roughness less than the first roughness.

A method includes etching a semiconductor substrate to form a trench, with the semiconductor substrate having a sidewall facing the trench, and depositing a first semiconductor layer extending into the trench. The first semiconductor layer includes a first bottom portion at a bottom of the trench, and a first sidewall portion on the sidewall of the semiconductor substrate. The first sidewall portion is removed to reveal the sidewall of the semiconductor substrate. The method further includes depositing a second semiconductor layer extending into the trench, with the second semiconductor layer having a second bottom portion over the first bottom portion, and a second sidewall portion contacting the sidewall of the semiconductor substrate. The second sidewall portion is removed to reveal the sidewall of the semiconductor substrate.

The present disclosure describes a method for forming a nitrogen-rich protective layer within a low-k layer of a metallization layer to prevent damage to the low-k layer from subsequent processing operations. The method includes forming, on a substrate, a metallization layer having conductive structures in a low-k dielectric. The method further includes forming a capping layer on the conductive structures, where forming the capping layer includes exposing the metallization layer to a first plasma process to form a nitrogen-rich protective layer below a top surface of the low-k dielectric, releasing a precursor on the metallization layer to cover top surfaces of the conductive structures with precursor molecules, and treating the precursor molecules with a second plasma process to dissociate the precursor molecules and form the capping layer. Additionally, the method includes forming an etch stop layer to cover the capping layer and top surfaces of the low-k dielectric.