Abstract: A process for forming a resistive random-access memory device, the process comprising the steps of: depositing a first electrode on a substrate; forming a porous resistive memory material layer on the first electrode, wherein the porous resistive memory layer is formed by (i) depositing a gaseous composition comprising a silicon precursor and a porogen precursor and, once deposited, (ii) removing the porogen precursor by exposing the composition to UV radiation; and depositing a second electrode on top of the porous resistive memory material layer.

Abstract: Described herein are compositions and methods using same for forming a silicon-containing film such as without limitation a silicon oxide, silicon nitride, silicon oxynitride, a carbon-doped silicon nitride, or a carbon-doped silicon oxide film on at least a surface of a substrate having a surface feature. In one aspect, the composition comprises at least one compound is selected from the group consisting of a siloxane, an trisilylamine-based compound, an organoaminodisilane compound, and a cyclic trisilazane compound.

Abstract: A method and composition for producing a porous low k dielectric film via chemical vapor deposition is provided. In one aspect, the method comprises the steps of: providing a substrate within a reaction chamber; introducing into the reaction chamber gaseous reagents including at least one structure-forming precursor comprising an alkyl-alkoxysilacyclic compound, and a porogen; applying energy to the gaseous reagents in the reaction chamber to induce reaction of the gaseous reagents to deposit a preliminary film on the substrate, wherein the preliminary film contains the porogen, and the preliminary film is deposited; and removing from the preliminary film at least a portion of the porogen contained therein and provide the film with pores and a dielectric constant of 2.7 or less. In certain embodiments, the structure-forming precursor further comprises a hardening additive.

Abstract: A particle trap for a remote plasma source includes a body structure having an inlet for coupling to a chamber of a remote plasma source and an outlet for coupling to a process chamber inlet. The particle trap for a remote plasma source also includes a gas channel formed in the body structure and in fluid communication with the body structure inlet and the body structure outlet. The gas channel can define a path through the body structure that causes particles in a gas passing from a first portion of the channel to strike a wall that defines a second portion of the gas channel at an angle relative to a surface of the wall. A coolant member can be in thermal communication with the gas channel.

Abstract: A particle trap for a remote plasma source includes a body structure having an inlet for coupling to a chamber of a remote plasma source and an outlet for coupling to a process chamber inlet. The particle trap for a remote plasma source also includes a gas channel formed in the body structure and in fluid communication with the body structure inlet and the body structure outlet. The gas channel can define a path through the body structure that causes particles in a gas passing from a first portion of the channel to strike a wall that defines a second portion of the gas channel at an angle relative to a surface of the wall. A coolant member can be in thermal communication with the gas channel.

Abstract: A system for producing excited gases for introduction to a semiconductor processing chamber. The system includes a plasma source for generating a plasma. The plasma source includes a plasma chamber and a gas inlet for receiving process gases from a gas source. A gas flow rate controller is coupled to the gas inlet for controlling an inlet flow rate of the process gases from the gas source to the plasma chamber via the gas inlet. The system includes a control loop for detecting a transition from a first process gas to a second process gas and for adjusting the inlet flow rate of the second process gas from about 0 sccm to about 10,000 sccm over a period of time greater than about 300 milliseconds to maintain transient heat flux loads applied by the plasma to an inner surface of the plasma chamber below a vaporization temperature of the plasma chamber.