Abstract: A showerhead for a processing chamber in a substrate processing system includes an upper portion having a lower surface and an upper surface and a faceplate. A lower surface of the faceplate is below the lower surface of the upper portion such that the showerhead extends into an interior volume of the processing chamber and the faceplate includes a plurality of holes arranged in a pattern to provide fluid communication between a remote plasma source above the showerhead and the interior volume of the processing chamber. A sidewall extends upward from an outer edge of the faceplate between the faceplate and the upper portion and the upper portion extends radially outward from the sidewall of the showerhead and is configured to be mounted on a sidewall of the processing chamber. A heater is embedded in the upper portion of the showerhead.

Abstract: A substrate processing system for selectively etching a layer on a substrate includes an upper chamber region, an inductive coil arranged around the upper chamber region and a lower chamber region including a substrate support to support a substrate. A gas distribution device is arranged between the upper chamber region and the lower chamber region and includes a plate with a plurality of holes. A cooling plenum cools the gas distribution device and a purge gas plenum directs purge gas into the lower chamber. A surface to volume ratio of the holes is greater than or equal to 4. A controller selectively supplies an etch gas mixture to the upper chamber and a purge gas to the purge gas plenum and strikes plasma in the upper chamber to selectively etch a layer of the substrate relative to at least one other exposed layer of the substrate.

Abstract: A substrate processing system for selectively etching a layer on a substrate includes an upper chamber region, an inductive coil arranged around the upper chamber region and a lower chamber region including a substrate support to support a substrate. A gas distribution device is arranged between the upper chamber region and the lower chamber region and includes a plate with a plurality of holes. A cooling plenum cools the gas distribution device and a purge gas plenum directs purge gas into the lower chamber. A surface to volume ratio of the holes is greater than or equal to 4. A controller selectively supplies an etch gas mixture to the upper chamber and a purge gas to the purge gas plenum and strikes plasma in the upper chamber to selectively etch a layer of the substrate relative to at least one other exposed layer of the substrate.

Abstract: Methods and apparatus for laterally etching unwanted material from the sidewalls of a recessed feature are described herein. In various embodiments, the method involves etching a portion of the sidewalls, depositing a protective film over a portion of the sidewalls, and cycling the etching and deposition operations until the unwanted material is removed from the entire depth of the recessed feature. Each etching and deposition operation may target a particular depth along the sidewalls of the feature. In some cases, the unwanted material is removed from the bottom of the feature up, and in other cases the unwanted material is removed from the top of the feature down. Some combination of these may also be used.

Abstract: Methods for controlled isotropic etching of layers of silicon oxide and germanium oxide with atomic scale fidelity are provided. The methods make use of NO activation of an oxide surface. Once activated, a fluorine-containing gas or vapor etches the activated surface. Etching is self-limiting as once the activated surface is removed, etching stops since the fluorine species does not spontaneously react with the un-activated oxide surface. These methods may be used in interconnect pre-clean applications, gate dielectric processing, manufacturing of memory devices, or any other applications where accurate removal of one or multiple atomic layers of material is desired.

Abstract: Methods and apparatus for laterally etching unwanted material from the sidewalls of a recessed feature are described herein. In various embodiments, the method involves etching a portion of the sidewalls, depositing a protective film over a portion of the sidewalls, and cycling the etching and deposition operations until the unwanted material is removed from the entire depth of the recessed feature. Each etching and deposition operation may target a particular depth along the sidewalls of the feature. In some cases, the unwanted material is removed from the bottom of the feature up, and in other cases the unwanted material is removed from the top of the feature down. Some combination of these may also be used.

Abstract: Methods and apparatus for laterally etching unwanted material from the sidewalls of a recessed feature are described herein. In various embodiments, the method involves etching a portion of the sidewalls, depositing a protective film over a portion of the sidewalls, and cycling the etching and deposition operations until the unwanted material is removed from the entire depth of the recessed feature. Each etching and deposition operation may target a particular depth along the sidewalls of the feature. In some cases, the unwanted material is removed from the bottom of the feature up, and in other cases the unwanted material is removed from the top of the feature down. Some combination of these may also be used.

Abstract: Methods and apparatus for laterally etching unwanted material from the sidewalls of a recessed feature are described herein. In various embodiments, the method involves etching a portion of the sidewalls, depositing a protective film over a portion of the sidewalls, and cycling the etching and deposition operations until the unwanted material is removed from the entire depth of the recessed feature. Each etching and deposition operation may target a particular depth along the sidewalls of the feature. In some cases, the unwanted material is removed from the bottom of the feature up, and in other cases the unwanted material is removed from the top of the feature down. Some combination of these may also be used.

Abstract: A method for selectively etching a silicon nitride layer on a substrate includes arranging a substrate on a substrate support of a substrate processing chamber. The substrate processing chamber includes an upper chamber region, an inductive coil arranged outside of the upper chamber region, a lower chamber region including the substrate support and a gas dispersion device. The gas dispersion device includes a plurality of holes in fluid communication with the upper chamber region and the lower chamber region. The method includes supplying an etch gas mixture to the upper chamber region and striking inductively coupled plasma in the upper chamber region by supplying power to the inductive coil. The etch gas mixture etches silicon nitride, promotes silicon dioxide passivation and promotes polysilicon passivation. The method includes selectively etching the silicon nitride layer on the substrate and extinguishing the inductively coupled plasma after a predetermined period.

Abstract: A substrate processing system for selectively etching a layer on a substrate includes an upper chamber region, an inductive coil arranged around the upper chamber region and a lower chamber region including a substrate support to support a substrate. A gas distribution device is arranged between the upper chamber region and the lower chamber region and includes a plate with a plurality of holes. A cooling plenum cools the gas distribution device and a purge gas plenum directs purge gas into the lower chamber. A surface to volume ratio of the holes is greater than or equal to 4. A controller selectively supplies an etch gas mixture to the upper chamber and a purge gas to the purge gas plenum and strikes plasma in the upper chamber to selectively etch a layer of the substrate relative to at least one other exposed layer of the substrate.

Abstract: Apparatuses for processing substrates are provided herein. Apparatuses include a plasma etch chamber having a showerhead and pedestal for holding a substrate having silicon nitride, at least one outlet for coupling to a vacuum, a solid non-functional silicon source, and a plasma generator. A solid silicon source may be upstream of a substrate, such as at or near a showerhead of a process chamber, or in a remote plasma generator. Apparatuses also include a plasma etch chamber, at least one outlet, a solid non-functional silicon source, a plasma generator, and a controller for controlling operations including instructions for causing introduction of a fluorinating gas and causing ignition of a plasma to form fluorine-containing etching species in the plasma etch chamber.

Abstract: Methods of selectively etching silicon nitride on a semiconductor substrate by providing silicon to the plasma to achieve high etch selectivity of silicon nitride to silicon-containing materials are provided. Methods involve providing silicon from a solid or fluidic silicon source or both. A solid silicon source may be upstream of a substrate, such as at or near a showerhead of a process chamber, or in a remote plasma generator. A silicon gas source may be flowed to the plasma during etch.

Abstract: A method for etching a substrate and removing byproducts includes a) setting process parameters of a processing chamber for a selective dry etch process; b) setting process pressure of the processing chamber to a first predetermined pressure in a range from 1 Torr to 10 Torr for the selective dry etch process; c) selectively etching a first film material of a substrate relative to a second film material of the substrate in the processing chamber during a first period; d) lowering pressure in the processing chamber to a second predetermined pressure that is less than the first predetermined pressure by a factor greater than or equal to 4; and e) purging the processing chamber at the second predetermined pressure for a second period.

Abstract: A method for etching a substrate and removing byproducts includes a) setting process parameters of a processing chamber for a selective dry etch process; b) setting process pressure of the processing chamber to a first predetermined pressure in a range from 1 Torr to 10 Torr for the selective dry etch process; c) selectively etching a first film material of a substrate relative to a second film material of the substrate in the processing chamber during a first period; d) lowering pressure in the processing chamber to a second predetermined pressure that is less than the first predetermined pressure by a factor greater than or equal to 4; and e) purging the processing chamber at the second predetermined pressure for a second period.

Abstract: A method for selectively etching a silicon nitride layer on a substrate includes arranging a substrate on a substrate support of a substrate processing chamber. The substrate processing chamber includes an upper chamber region, an inductive coil arranged outside of the upper chamber region, a lower chamber region including the substrate support and a gas dispersion device. The gas dispersion device includes a plurality of holes in fluid communication with the upper chamber region and the lower chamber region. The method includes supplying an etch gas mixture to the upper chamber region and striking inductively coupled plasma in the upper chamber region by supplying power to the inductive coil. The etch gas mixture etches silicon nitride, promotes silicon dioxide passivation and promotes polysilicon passivation, The method includes selectively etching the silicon nitride layer on the substrate and extinguishing the inductively coupled plasma after a predetermined period.

Abstract: Methods for controlled isotropic etching of layers of silicon oxide and germanium oxide with atomic scale fidelity are provided. The methods make use of NO activation of an oxide surface. Once activated, a fluorine-containing gas or vapor etches the activated surface. Etching is self-limiting as once the activated surface is removed, etching stops since the fluorine species does not spontaneously react with the un-activated oxide surface. These methods may be used in interconnect pre-clean applications, gate dielectric processing, manufacturing of memory devices, or any other applications where accurate removal of one or multiple atomic layers of material is desired.

Abstract: Methods of selectively etching silicon nitride on a semiconductor substrate by providing silicon to the plasma to achieve high etch selectivity of silicon nitride to silicon-containing materials are provided. Methods involve providing silicon from a solid or fluidic silicon source or both. A solid silicon source may be upstream of a substrate, such as at or near a showerhead of a process chamber, or in a remote plasma generator. A silicon gas source may be flowed to the plasma during etch.

Abstract: Methods for controlled isotropic etching of layers of silicon oxide and germanium oxide with atomic scale fidelity are provided. The methods make use of NO activation of an oxide surface. Once activated, a fluorine-containing gas or vapor etches the activated surface. Etching is self-limiting as once the activated surface is removed, etching stops since the fluorine species does not spontaneously react with the un-activated oxide surface. These methods may be used in interconnect pre-clean applications, gate dielectric processing, manufacturing of memory devices, or any other applications where accurate removal of one or multiple atomic layers of material is desired.

Abstract: Methods for controlled isotropic etching of layers of silicon oxide and germanium oxide with atomic scale fidelity are provided. The methods make use of NO activation of an oxide surface. Once activated, a fluorine-containing gas or vapor etches the activated surface. Etching is self-limiting as once the activated surface is removed, etching stops since the fluorine species does not spontaneously react with the un-activated oxide surface. These methods may be used in interconnect pre-clean applications, gate dielectric processing, manufacturing of memory devices, or any other applications where accurate removal of one or multiple atomic layers of material is desired.

Abstract: Methods of selectively etching silicon nitride are provided. Silicon nitride layers are exposed to a fluorinating gas and nitric oxide (NO), which may be formed by reacting nitrous oxide (N2O) and oxygen (O2) in a plasma. Methods also include defluorinating the substrate prior to turning off the plasma to increase etch selectivity of silicon nitride.