Abstract: Multiple, sequential pulses of radiofrequency power are supplied to an electrode of a plasma processing chamber to control a plasma within the plasma processing chamber. Each of the pulses of radiofrequency power includes a first duration over which a first radiofrequency power profile exists, immediately followed by a second duration over which a second radiofrequency power profile exists. The first radiofrequency power profile has greater radiofrequency power than the second radiofrequency power profile. The first duration is less than the second duration. And, the sequential pulses of radiofrequency power are separated from each other by a third duration. A radiofrequency signal generation system is provided to generate and control the multiple, sequential pulses of radiofrequency power.

Abstract: A substrate processing system includes a processing chamber including a substrate support to support a substrate. A coil includes at least one terminal. An RF source configured to supply RF power to the coil. A dielectric window is arranged on one surface of the processing chamber adjacent to the coil. A contamination reducer includes a first plate that is arranged between the at least one terminal of the coil and the dielectric window.

Abstract: A substrate processing system includes a processing chamber including a substrate support to support a substrate. A coil includes at least one terminal. An RF source configured to supply RF power to the coil. A dielectric window is arranged on one surface of the processing chamber adjacent to the coil. A contamination reducer includes a first plate that is arranged between the at least one terminal of the coil and the dielectric window.

Abstract: Methods of and apparatuses for laterally etching semiconductor substrates using an atomic layer etch process involving exposing an oxidized surface of a semiconductor substrate to a fluorine-containing etch gas and heating the substrate to remove non-volatile etch byproducts by a sublimation mechanism are provided herein. Methods also including additionally pulsing a hydrogen-containing gas when pulsing the fluorine-containing etch gas. Apparatuses also include an ammonia mixing manifold suitable for separately preparing and mixing ammonia for use in various tools.

Abstract: A substrate processing system includes a processing chamber including a substrate support to support a substrate. A coil includes at least one terminal. An RF source configured to supply RF power to the coil. A dielectric window is arranged on one surface of the processing chamber adjacent to the coil. A contamination reducer includes a first plate that is arranged between the at least one terminal of the coil and the dielectric window.

Abstract: Methods of and apparatuses for laterally etching semiconductor substrates using an atomic layer etch process involving exposing an oxidized surface of a semiconductor substrate to a fluorine-containing etch gas and heating the substrate to remove non-volatile etch byproducts by a sublimation mechanism are provided herein. Methods also including additionally pulsing a hydrogen-containing gas when pulsing the fluorine-containing etch gas. Apparatuses also include an ammonia mixing manifold suitable for separately preparing and mixing ammonia for use in various tools.

Abstract: Methods of and apparatuses for laterally etching semiconductor substrates using an atomic layer etch process involving exposing an oxidized surface of a semiconductor substrate to a fluorine-containing etch gas and heating the substrate to remove non-volatile etch byproducts by a sublimation mechanism are provided herein. Methods also including additionally pulsing a hydrogen-containing gas when pulsing the fluorine-containing etch gas. Apparatuses also include an ammonia mixing manifold suitable for separately preparing and mixing ammonia for use in various tools.

Abstract: Methods of and apparatuses for laterally etching semiconductor substrates using an atomic layer etch process involving exposing an oxidized surface of a semiconductor substrate to a fluorine-containing etch gas and heating the substrate to remove non-volatile etch byproducts by a sublimation mechanism are provided herein. Methods also including additionally pulsing a hydrogen-containing gas when pulsing the fluorine-containing etch gas. Apparatuses also include an ammonia mixing manifold suitable for separately preparing and mixing ammonia for use in various tools.

Abstract: A method for etching features into a silicon containing etch layer is provided. The etch layer is placed into a plasma processing chamber. An etch gas is flowed into the plasma processing chamber. The etch gas is formed into an etch plasma, wherein the etch plasma etches features into the silicon containing layer leaving silicon containing residue. The flow of etch gas into the plasma processing chamber is stopped. A dry clean gas is flowed into the plasma processing chamber, wherein the dry clean gas comprises NH3 and NF3. The dry clean gas is formed into a plasma, wherein the silicon containing residue is exposed to the dry clean gas plasma, and wherein at least some or all of the silicon containing residue is formed into ammonium containing compounds. The flow of the dry clean gas is stopped. The ammonium compounds are sublimated from the films.