Semiconductor systems and methods may include a semiconductor processing chamber having a gas box defining an access to the semiconductor processing chamber. The chamber may include a spacer characterized by a first surface with which the gas box is coupled, and the spacer may define a recessed ledge on an interior portion of the first surface. The chamber may include a support bracket seated on the recessed ledge that extends along a second surface of the spacer. The chamber may also include a gas distribution plate seated on the support bracket.

A substrate support in a substrate processing system includes a baseplate, a ceramic layer, and a bond layer. The ceramic layer is arranged on the baseplate to support a substrate. The bond layer is arranged between the ceramic layer and the baseplate. A seal is arranged between the ceramic layer and the baseplate around an outer perimeter of the bond layer. The seal includes an inner layer formed adjacent to the bond layer and an outer layer formed adjacent to the inner layer such that the inner layer is between the outer layer and the bond layer. The inner layer comprises a first material and the outer layer comprises a second material.

A method of depositing silicon nitride films on semiconductor substrates processed in a micro-volume of a plasma enhanced atomic layer deposition (PEALD) reaction chamber wherein a single semiconductor substrate is supported on a ceramic surface of a pedestal and process gas is introduced through gas outlets in a ceramic surface of a showerhead into a reaction zone above the semiconductor substrate, includes (a) cleaning the ceramic surfaces of the pedestal and showerhead with a fluorine plasma, (b) depositing a halide-free atomic layer deposition (ALD) oxide undercoating on the ceramic surfaces, (c) depositing a precoating of ALD silicon nitride on the halide-free ALD oxide undercoating, and (d) processing a batch of semiconductor substrates by transferring each semiconductor substrate into the reaction chamber and depositing a film of ALD silicon nitride on the semiconductor substrate supported on the ceramic surface of the pedestal.

A substrate processing apparatus includes: a process chamber where a substrate is processed; a substrate support, disposed in the process chamber, where the substrate is placed; a transfer chamber disposed under the process chamber; a partition dividing the process and transfer chambers; a first heating unit disposed in the substrate support to heat the substrate and the process chamber; a second heating unit disposed in the transfer chamber to heat the transfer chamber; a process gas supply unit to supply a process gas into the process chamber; a first cleaning gas supply unit to supply a cleaning gas into the process chamber; a second cleaning gas supply unit to supply the cleaning gas into the transfer chamber; and a control unit to control the first heating unit, the second heating unit, the process gas supply unit, the first cleaning gas supply unit and the second cleaning gas supply unit.

A plasma processing system having at least one processing chamber comprising at least two sub-chambers is provided. The two plasma sub-chambers are in plasma flow or gas flow communication through a passage, which is controlled by a gate. The gate may be operated to allow plasma migration between the two sub-chambers to occur at different conductance rates. In one example, the gate comprises two plates with openings through the plates. At least one of the plates may be rotatable relative to the other plates to govern the conductance rate of the plasma from one sub-chamber to the other sub-chamber.

A substrate processing apparatus having a simplified exhaust structure includes: a substrate supporting unit configured to support a substrate; a first lid on the substrate supporting unit, the first lid including at least one processing unit; a second lid under the first lid, the second lid including a partition wall; and a support arranged under the first lid and the second lid and including an opening and a seating portion on the opening, wherein the second lid is on the seating portion of the support.

An atmospheric pressure pulsed arc plasma source and method of using including a housing having a housing opening therein; an insulator tube having an insulator tube opening therein, retained within the housing opening; and a conductive tube, retained within the insulator tube opening. A nozzle is retained by the housing. A feed path is defined in the conductive tube and the nozzle and a gas feed port is operatively coupled to the feed path. Feedstock is provided in the feed path and electrically coupled to the conductive tube. A pulsed DC power source provides a pulsed voltage to the conductive tube. The plasma source emits a discharge stream having a temperature that is less than 50° C. from the nozzle and a coating is formed on a substrate.

A method of manufacturing a semiconductor device, includes: supplying a first precursor and a first nitriding agent onto a substrate having a surface formed thereon with an oxygen-containing film in order to form an initial film on the oxygen-containing film; modifying the initial film into a first nitride film by nitriding the initial film with plasma; and supplying a second precursor and a second nitriding agent onto the substrate in order to form a second nitride film on the first nitride film.

Disclosed are methods of and systems for depositing a film. The methods may include: (a) determining process conditions, including a flow condition of a curtain gas that flows around the periphery of each station in the chamber, for performing film deposition in the chamber, (b) flowing the curtain gas to each station in the chamber during film deposition according to the process conditions determined in (a), (c) determining, during or after (b), an adjusted flow condition of the curtain gas in the chamber to improve substrate nonuniformity, and (d) flowing, after (c), the curtain gas during film deposition according to the adjusted flow condition determined in (c). The systems may include a gas delivery system, a processing chamber, and a controller having control logic for performing one or more of (a)-(d).

A substrate processing apparatus having an improved exhaust structure includes a reaction space formed between a processing unit and a substrate support unit, an exhaust unit surrounding the reaction space, an exhaust port with a channel inside, a partition wall with an exhaust line inside, wherein the channel of the exhaust port connects the exhaust unit and the exhaust line.