Embodiments of components for use in substrate process chambers are provided herein. In some embodiments, a component for use in a substrate process chamber includes: a body having an opening extending partially through the body from a top surface of the body, wherein the opening includes a threaded portion for fastening the body to a second process chamber component, wherein the threaded portion includes a plurality of threads defining a plurality of rounded crests and a plurality of rounded roots, and wherein a depth of the threaded portion, being a radial distance between a rounded crest of the plurality of rounded crests and an adjacent root of the plurality of rounded roots, decreases from a first depth to a second depth at a last thread of the plurality of threads.

Systems and methods are provided herein to improve the efficiency of an atomic layer deposition (ALD) cycle by providing an improved purge block design. The improved purge block prevents gas mixing, regardless of the rotational speed of the platen, by providing a lower cavity on an underside of the purge block, and in some embodiments, by providing an upper cavity on a topside of the purge block. The lower/upper cavity provides a gas conduction path that distributes purge gas evenly beneath/above the purge block and provides uniform gas flow conductance within the lower/upper cavity. Compared to conventional purge block designs, the improved purge block design described herein provides a narrower, yet more effective isolation barrier, which prevents gas mixing even at high rotational speeds of the platen.

Exemplary semiconductor processing chambers may include a substrate support including a top surface. A peripheral edge region of the top surface may be recessed relative to a medial region of the top surface. The chambers may include a pumping liner disposed about an exterior surface of the substrate support. The chambers may include a liner disposed between the substrate support and the pumping liner. The liner may be spaced apart from the exterior surface to define a purge lumen between the liner and the substrate support. The chambers may include an edge ring seated on the peripheral edge region. The edge ring may extend beyond a peripheral edge of the substrate support and above a portion of the liner. A gap may be formed between a bottom surface of the edge ring and a top surface of the liner. The gap and the purge lumen may be fluidly coupled.

A semiconductor manufacturing apparatus includes: a stage installed inside a processing chamber and holding a semiconductor substrate having a high-k insulating film including silicate; and a gas supply line including a first system supplying reactive gas to the processing chamber and a second system supplying catalytic gas to the processing chamber, wherein mixed gas which includes complex forming gas reacting with a metal element included in the high-k insulating film to form a first volatile organometallic complex and complex stabilizing material gas increasing stability of the first organometallic complex is supplied as the reactive gas, and catalytic gas using a second organometallic complex, which modifies the high-k insulating film and promotes a formation reaction of the first organometallic complex, as a raw material is supplied.

A diffuser for diffusing a gas includes a base portion and a head portion fluidly coupled to the base portion. The head portion includes a diffuser element configured to diffuse a first fraction of the gas through a circumference of the diffuser element and a second fraction of the gas through an end surface of the diffuser element. The head portion further includes a connecting structure having a first connecting portion configured to receive a portion of the diffuser element therein and a second connecting portion protruding outwardly from the first connecting portion and configured to couple to the base portion.

The present invention refers to a method for the preparation of organic-inorganic hybrid materials which comprises the combination of ALD and MPI techniques, to an organic-inorganic hybrid material obtainable by said method, and to the uses of said organic-inorganic hybrid material.

Apparatus, system, and method of depositing thin and ultra-thin parylene are described. In an example, a core deposition chamber is used. The core deposition chamber includes a base and a rigid, removable cover configured to mate and seal with the base to create the core deposition chamber and to define an inside and an outside of the core deposition chamber. The core deposition chamber also includes a conduit through a top of the cover. The conduit has a lumen connecting the inside to the outside of the core deposition chamber. The lumen has a length and a cross-section. The cross-section has a width between 50 μm and 6000 μm. The length is less than 140 times the cross-section width. The core deposition chamber can be placed in an outer deposition chamber and can achieve parylene deposition less than 1 μm thick inside the core deposition chamber.

The method relates to a method of forming an enhanced unexposed photoresist layer from an unexposed photoresist layer on a substrate by increasing the sensitivity of the unexposed photoresist to exposure radiation. The method comprises: providing the substrate with the unexposed photoresist layer in a reaction chamber; providing a first precursor comprising a portion of a photosensitizer sensitive to exposure radiation in the reaction chamber; and, infiltrating the unexposed photoresist layer on the substrate with the first precursor.

A method for depositing a silicon nitride film is provided to fill a recessed pattern formed in a surface of a substrate with a silicon nitride film. In the method, a first silicon nitride film is deposited in the recessed pattern formed in the surface of the substrate. The first silicon nitride film has a V-shaped cross section decreasing its film thickness upward from a bottom portion of the recessed pattern. A second silicon nitride film conformal to a surface shape of the first silicon nitride film is deposited.

Methods for manufacturing a diffuser plate for a PECVD chamber are provided. The methods provide for applying a compliant abrasive medium to round the sharp edges at corners of the output holes on a contoured downstream side of a gas diffuser plate. By rounding the edges of the output holes reduces the flaking of deposited materials on the downstream side of the gas diffuser plate and reduces the amount of undesirable particles generated during the PECVD deposition process.