Semiconductor devices, FinFET devices and methods of forming the same are provided. In accordance with some embodiments, a semiconductor device includes a substrate, a first gate stack, a spacer, a first dielectric layer, a shielding layer and a connector. The first gate stack is over the substrate. The spacer is disposed on and contacted to at least one sidewall of the first gate stack. The first dielectric layer is aside the spacer. The shielding layer covers a top surface of the spacer and a top surface of the first dielectric layer. The connector contacts a portion of a top surface of the first gate stack.

A substrate processing method for forming a nitride film on a substrate, includes: a raw material gas supply step of supplying a raw material gas containing an element to be nitrided; a hydrogen gas supply step of, after the raw material gas supply step, supplying a hydrogen gas activated by plasma; a thermal nitriding step of supplying a first nitriding gas containing nitrogen activated by heat and nitriding the element; and a plasma nitriding step of supplying a second nitriding gas containing nitrogen activated by plasma and nitriding the element.

Described herein is a technique capable of improving the uniformity of the film formation among the substrates. According to the technique described herein, there is provided a configuration including: a reaction tube having a process chamber where a plurality of substrates are processed; a buffer chamber protruding outward from the reaction tube and configured to supply a process gas to the process chamber, the buffer chamber including: a first nozzle chamber where a first nozzle is provided; and a second nozzle chamber where a second nozzle is provided; an opening portion provided at a lower end of an inner wall of the reaction tube facing the buffer chamber; and a shielding portion provided at a communicating portion of the opening portion between the second nozzle chamber and the process chamber.

An epitaxy substrate and a method of manufacturing the same are provided. The epitaxy substrate includes a silicon substrate and a silicon carbide layer. The silicon substrate has a first surface and a second surface opposite to each other, and the first surface is an epitaxy surface. The silicon carbide layer is located in the silicon substrate, and a distance between the silicon carbide layer and the first surface is between 100 angstroms (Å) and 500 angstroms.

Embodiments of the present disclosure generally relate to processes for forming silicon- and boron-containing films for use in, e.g., spacer-defined patterning applications. In an embodiment, a spacer-defined patterning process is provided. The process includes disposing a substrate in a processing volume of a processing chamber, the substrate having patterned features formed thereon, and flowing a first process gas into the processing volume, the first process gas comprising a silicon-containing species, the silicon-containing species having a higher molecular weight than SiH.sub.4. The process further includes flowing a second process gas into the processing volume, the second process gas comprising a boron-containing species, and depositing, under deposition conditions, a conformal film on the patterned features, the conformal film comprising silicon and boron.

A method for processing a substrate includes performing a cyclic plasma process including a plurality of cycles, each cycle of the plurality of cycles including purging a plasma processing chamber including the substrate with a first deposition gas including carbon. The substrate includes a first layer including silicon and a second layer including a metal oxide. The method further includes exposing the substrate to a first plasma generated from the first deposition gas to selectively deposit a first polymeric film over the first layer relative to the second layer; purging the plasma processing chamber with an etch gas including fluorine; and exposing the substrate to a second plasma generated from the etch gas to etch the second layer.

Provided is a composition for forming a silica layer, the composition containing a silicon-containing polymer and a solvent, wherein a silica layer formed of the composition for forming the silica layer satisfies Relation 1. The definition of Relation 1 is as described in the specification. The definition of Relation 1 is the same as described in the specification.

A method for manufacturing a semiconductor device includes supplying a silicon-containing gas to a substrate having a recess formed in a surface of the substrate to deposit a silicon film in the recess, supplying, to the substrate, a first etching gas having a first etching profile in which an amount of etching for an upper portion of the recess in a depth direction and an amount of etching for a lower portion of the recess in the depth direction are different from each other, to etch the silicon film in the recess, supplying, to the substrate, a second etching gas having a second etching profile that is different from the first etching profile of the first etching gas to etch the silicon film in the recess, and additionally depositing the silicon film on the already deposited silicon film etched by the second etching gas.

Semiconductor device is provided. The semiconductor device includes a substrate and a fin on the substrate. The fin includes channel layers stacked along a normal direction of a substrate surface. The channel layers includes a first channel layer and a second channel layer under the first channel layer, and the second channel layer has recessed sidewalls with respect to corresponding sidewalls of the first channel layer. The semiconductor device further includes a gate structure, disposed around each of the first channel layer and the second channel layer; and a doped source/drain layer in the fin on two sides of the gate structure. The doped source/drain layer is respectively connected to the second channel layer and the first channel layer.

Systems and methods are described herein to include an epitaxial metal layer between a rare earth oxide and a semiconductor layer. Systems and methods are described to grow a layered structure, comprising a substrate, a first rare earth oxide layer epitaxially grown over the substrate, a first metal layer epitaxially grown over the rare earth oxide layer, and a first semiconductor layer epitaxially grown over the first metal layer. Specifically, the substrate may include a porous portion, which is usually aligned with the metal layer, with or without a rare earth oxide layer in between.