A chemical vapor deposition method for producing a dielectric film, the method comprising: providing a substrate into a reaction chamber; introducing gaseous reagents into the reaction chamber wherein the gaseous reagents comprise a silicon precursor comprising an silicon compound having Formula I as defined herein and applying energy to the gaseous reagents in the reaction chamber to induce reaction of the gaseous reagents to deposit a film on the substrate. The film as deposited is suitable for its intended use without an optional additional cure step applied to the as-deposited film.

A system and method of forming a planarization layer on a substrate is disclosed. The method can include holding a superstrate with a superstrate chuck, the superstrate chuck positioned relative to a diffusing element, where the diffusing element includes a pattern and the superstrate chuck includes one or more geometric features, and where the pattern of the diffusing element aligns with the one or more geometric features of the superstrate chuck. The method can also include dispensing a formable material over the substrate, contacting the formable material over the substrate with a superstrate, providing a set of beams that pass through the diffusing element to cure the formable material over the substrate and form a layer over the substrate while the superstrate is contacting the formable material.

The present disclosure relates to a method of fabricating a semiconductor structure, the method includes forming an opening and depositing a metal layer in the opening. The depositing includes performing one or more deposition cycles, wherein each deposition cycle includes flowing a first precursor into a deposition chamber and performing an ultraviolet (UV) radiation process on the first precursor. The method further includes performing a first purging process in the deposition chamber to remove at least a portion of the first precursor, flowing a second precursor into the deposition chamber, and purging the deposition chamber to remove at least a portion of the second precursor.

A method for forming a silicon nitride film that may be carbon doped via a plasma ALD process includes introducing a substrate into a reactor, which is heated to up to about 600° C. At least one silicon precursor as defined herein and having one or two Si—C—Si linkages is introduced to form a chemisorbed film on the substrate. The reactor is then purged of any unconsumed precursors and/or reaction by-products with a suitable inert gas. A plasma comprising nitrogen is introduced into the reactor to react with the chemisorbed film to form the silicon nitride film that may be carbon doped. The reactor is again purged of any reaction by-products with a suitable inert gas. The steps are repeated as necessary to bring the deposited silicon nitride film that may be carbon doped to a predetermined thickness.

A method for etching silicon at cryogenic temperatures is provided. The method includes forming an inert layer from condensation of a noble gas at cryogenic temperatures on exposed surfaces such as the sidewalls of a feature to passivate the sidewalls prior to the etching process. The method further includes flowing a fluorine-containing precursor gas into the chamber to form a fluorine-containing layer on the inert layer. The method further includes exposing the fluorine-containing layer and the inert layer to an energy source to form a passivation layer on the exposed portions of the substrate and exposing the substrate to ions to etch the substrate.

The present disclosure relates to a method of fabricating a semiconductor structure, the method includes forming an opening and depositing a metal layer in the opening. The depositing includes performing one or more deposition cycles, wherein each deposition cycle includes flowing a first precursor into a deposition chamber and performing an ultraviolet (UV) radiation process on the first precursor. The method further includes performing a first purging process in the deposition chamber to remove at least a portion of the first precursor, flowing a second precursor into the deposition chamber, and purging the deposition chamber to remove at least a portion of the second precursor.

A semiconductor device includes a gate structure on a substrate, an offset spacer adjacent to the gate structure, a main spacer around the offset spacer, a source/drain region adjacent to two sides of the main spacer, a contact etch stop layer (CESL) adjacent to the main spacer, and an interlayer dielectric (ILD) layer around the CESL. Preferably, a dielectric constant of the offset spacer is higher than a dielectric constant of the main spacer.

Plasma processing apparatus and associated methods are provided. In one example, a plasma processing apparatus includes a plasma chamber. The plasma processing apparatus includes a dielectric wall forming at least a portion of the plasma chamber. The plasma processing apparatus includes an inductive coupling element located proximate the dielectric wall. The plasma processing apparatus includes an ultraviolet light source configured to emit an ultraviolet light beam onto a metal surface that faces an interior volume of the plasma chamber. The plasma processing apparatus includes a controller configured to control the ultraviolet light source.

A semiconductor device and a method of forming the same are provided. The method includes forming a trench in a substrate. A liner layer is formed along sidewalls and a bottom of the trench. A silicon-rich layer is formed over the liner layer. Forming the silicon-rich layer includes flowing a first silicon precursor into a process chamber for a first time interval, and flowing a second silicon precursor and a first oxygen precursor into the process chamber for a second time interval. The second time interval is different from the first time interval. The method further includes forming a dielectric layer over the silicon-rich layer.

A method for depositing a silicon-containing film, the method comprising: placing a substrate comprising at least one surface feature into a flowable CVD reactor which is at a temperature of from about −20° C. to about 100° C.; increasing pressure in the reactor to at least 10 torr; and introducing into the reactor at least one silicon-containing compound having at least one acetoxy group to at least partially react the at least one silicon-containing compound to form a flowable liquid oligomer wherein the flowable liquid oligomer forms a silicon oxide coating on the substrate and at least partially fills at least a portion of the at least one surface feature. Once cured, the silicon oxide coating has a low k and excellent mechanical properties.