The present technology includes improved gas distribution designs for forming uniform plasmas during semiconductor processing operations or for treating the interior of semiconductor processing chambers. While conventional gas distribution assemblies may receive a specific reactant or reactant ratio which is then distributed into the plasma region, the presently described technology allows for improved control of the reactant input distribution. The technology allows for separate flows of reactants to different regions of the plasma to offset any irregularities observed in process uniformity. A first precursor may be delivered to the center of the plasma above the center of the substrate/pedestal while a second precursor may be delivered to an outer portion of the plasma above an outer portion of the substrate/pedestal. In so doing, a substrate residing on the pedestal may experience a more uniform etch or deposition profile across the entire surface.

There is provided a plasma generating device that includes a first electrode connected to a high-frequency power supply, and a second electrode to be grounded, a buffer structure configured to form a buffer chamber that accommodates the first and second electrodes wherein the first electrode and the second electrode are alternately arranged such that a number of electrodes of the first electrode and the second electrode are in an odd number of three or more in total, and wherein the second electrode is used in common for two of the first electrode being respectively adjacent to the second electrode used in common, and wherein a gas supply port that supplies gas into a process chamber is installed on a wall surface of the buffer structure.

A deposition apparatus including: a processing chamber; a rotary table provided in the processing chamber; a first processing region provided at a predetermined position in a circumferential direction of the rotary table; a second processing region provided downstream of the first processing region in the circumferential direction of the rotary table; a third processing region provided downstream of the second processing region in the circumferential direction of the rotary table; a first heater provided above the rotary table in the second processing region; and a plasma generator. The plasma generator includes: a protrusion having a longitudinally elongated shape in a planar view extending along a radius of the rotary table in a portion of an upper surface of the processing chamber, and protruding upward from the upper surface; and a coil wound along a side surface of the protrusion and has a longitudinally elongated shape in a planar view.

A substrate support assembly includes a ground shield and a heater that is surrounded by the ground shield. The ground shield includes a plate. In one embodiment, the ground shield is composed of a ceramic body and includes an electrically conductive layer, a first protective layer on the upper surface of the plate. In another embodiment, the ground shield is composed of an electrically conductive body and a first protective layer on the upper surface of the plate.

There is provided a substrate processing apparatus that includes a process chamber in which at least one substrate is processed; a gas supplier configured to supply a gas; and a buffer structure. The buffer structure includes at least two plasma generation regions in which gas is converted into plasma by a pair of electrodes connected to a high-frequency power supply and an electrode to be grounded, a first gas supply port that supplies a gas generated in a first plasma generation region among the at least two plasma generation regions, and a second gas supply port that supplies a gas generated in a second plasma generation region among the at least two plasma generation regions.

A plasma processing apparatus for processing an object to be processed with plasma, includes: a stage on which the object to be processed is placed; an electrode arranged at a position facing the stage and to which high-frequency power having a frequency of 30 MHz or more is supplied; and a waveguide configured to propagate electromagnetic waves generated based on the high-frequency power to a plasma processing space formed between the stage and the electrode, wherein the waveguide is formed in an annular shape in a plan view so that an end portion of the waveguide near the plasma processing space surrounds an outer periphery of the electrode, a plurality of pins are provided to protrude into the waveguide, and the plurality of pins are arranged at respective positions separated from one another along a circumferential direction in the plan view.

An apparatus for forming a plasma may include one or more coupling ports to accept and RF current. The apparatus may additionally include a receptacle to accommodate one or more gases, in which the receptacle is oriented along a first axis. The apparatus may additionally include an RF coupling structure, oriented in a plane and substantially surrounding the receptacle, the RF coupling structure can be configured to conduct an RF current to bring about formation of the plasma within the receptacle. The apparatus may further include one or more linkages, coupled to the RF coupling structure, which may permit the plane of the RF coupling structure to pivot about a second axis so as to tilt the plane of the RF coupling structure toward the first axis.

An apparatus includes an electrostatic chuck and located within a vacuum enclosure. A plurality of conductive plates can be embedded in the electrostatic chuck, and a plurality of plate bias circuits can be configured to independently electrically bias a respective one of the plurality of conductive plates. Alternatively or additionally, a plurality of spot lamp zones including a respective set of spot lamps can be provided between a bottom portion of the vacuum enclosure and a backside surface of the electrostatic chuck. The plurality of conductive plates and/or the plurality of spot lamp zones can be employed to locally modify chucking force and to provide local temperature control.

A wafer fabricating system includes a wafer chuck, a gas inlet port, a fluid inlet port, first and second arc-shaped channels, a gas source, and a fluid containing source. The wafer chuck has a top surface, and orifices are formed on the top surface. The gas inlet port is formed in the wafer chuck and located underneath a fan-shaped sector of the top surface, wherein the gas inlet port is fluidly communicated with the orifices. The fluid inlet port is formed in the wafer chuck. The first and second arc-shaped channels are fluidly communicated with the fluid inlet port and located underneath the fan-shaped sector of the top surface and located at opposite sides of the gas inlet port from a top view. The gas source fluidly is connected to the gas inlet port. The fluid containing source fluidly is connected to the fluid inlet port.

Exemplary semiconductor processing systems may include a chamber body having sidewalls and a base. The semiconductor processing systems may include a substrate support extending through the base of the chamber body. The substrate support may include a support plate. The substrates support may include a shaft coupled with the support plate. The semiconductor processing systems may include a liner positioned within the chamber body and positioned radially outward of a peripheral edge of the support plate. An inner surface of the liner may include an emissivity texture.