A plasma processing apparatus includes a process container, a power supply configured to supply radio frequency or microwave power for generating plasma in the process container, a plurality of gas nozzles, each having a gas flow passage therein, and a plurality of protrusions formed integrally with a ceiling wall and/or a sidewall that defines the process container, the plurality of protrusions protruding from the ceiling wall and/or the sidewall. Each of the plurality of protrusions has a gas hole at a leading end of the protrusion. The ceiling wall and/or the sidewall has recesses in which the plurality of gas nozzles is arranged, respectively, such that the gas flow passage of each of the plurality of gas nozzles communicates with the gas hole of each of the plurality of protrusions.

According to an embodiment, an apparatus for a plasma processing system is provided. The apparatus includes an interface, a radiating structure, and conductive offsets. The interface includes a first conductive plate couplable to an RF source, a second conductive plate disposed between the RF source and the first conductive plate, and conductive concentric ring structures disposed between the second conductive plate and a substrate holder. The conductive offsets are arranged to couple the conductive concentric ring structures to the radiating structure.

Some embodiments provide a magnetron sputtering apparatus including a vacuum chamber within which a controlled environment may be established, a target comprising one or more sputterable materials, wherein the target includes a racetrack-shaped sputtering zone that extends longitudinally along a longitudinal axis and comprises a straightaway area sandwiched between a first turnaround area and a second turnaround area, a gas distribution system that supplies a first gas mixture to the first turnaround area and/or the second turnaround area and supplies a second gas mixture to the straightaway area, wherein the first gas mixture reduces a sputtering rate relative to the second gas mixture. In some cases, the first gas mixture includes inert gas having a first atomic weight and the second gas mixture includes inert gas having a second atomic weight, wherein the second atomic weight is heavier than the first atomic weight.

A method and apparatus for reducing as-deposited and metastable defects relative to amorphous silicon (a-Si) thin films, its alloys and devices fabricated therefrom that include heating an earth shield positioned around a cathode in a parallel plate plasma chemical vapor deposition chamber to control a temperature of a showerhead in the deposition chamber in the range of 350° C. to 600° C. An anode in the deposition chamber is cooled to maintain a temperature in the range of 50° C. to 450° C. at the substrate that is positioned at the anode. In the apparatus, a heater is embedded within the earth shield and a cooling system is embedded within the anode.

A gas distribution device for a substrate processing system includes an upper plate including a first hole and a plurality of second holes and a lower plate. The lower plate includes a recessed region formed in one of an upper surface of the lower plate and a lower surface of the upper plate. The recessed region defines a plenum volume between the upper plate and the lower plate. The lower plate further includes a raised fence located within the recessed region. The fence separates the plenum volume into a first plenum and a second plenum, the first plenum is in fluid communication with the first hole, and the second plenum is in fluid communication with the plurality of second holes.

Provided is a plasma reactor including a reactor body having a gas inlet at a side thereof, a gas outlet at another side thereof, and an annular loop space therein, a magnetic core provided in a shape surrounding a portion of the reactor body, and wound with a primary coil for receiving power from a power unit, so as to generate plasma by exciting a gas in the annular loop space, and a control unit for determining whether the plasma is in an off state, by comparing, to a reference value, an electrical parameter related to an output of the primary coil.

A plasma generating apparatus according to an embodiment of the present invention comprises: a pair of electrodes arranged in a dielectric discharge tube; an initial discharge induction coil module; and a main discharge induction coil module. The initial discharge induction coil module and the main discharge induction coil module are connected to an RF power source, and the RF power source provides RF power having different resonance frequencies to the initial discharge induction coil module and the main discharge induction coil module, respectively.

The inventive concept provides a substrate treating apparatus. In an embodiment the substrate treating apparatus includes a process chamber having a treating space therein for treating a substrate; a substrate support unit configured to support the substrate in the treating space; and a microwave application unit configured to apply a microwave to the treating space, and wherein the microwave application unit comprises a microwave power generator based on a solid state device.

An ion source having an extraction plate with a variable thickness is disclosed. The extraction plate has a protrusion on its interior or exterior surface proximate the extraction aperture. The protrusion increases the thickness of the extraction aperture in certain regions. This increases the loss area in those regions, which serves as a sink for ions and electrons. In this way, the plasma density is decreased more significantly in the regions where the extraction aperture has a greater thickness. The shape of the protrusion may be modified to achieve the desired plasma uniformity. Thus, it may be possible to create an extracted ion beam having a more uniform ion density. In some tests, the uniformity of the beam current along the width direction was improved by between 20% and 50%.

A baseplate for a substrate support includes a heater layer configured to selectively heat the baseplate and a heat spreader disposed between the heater layer and an upper surface of the baseplate. The heat spreader is configured to distribute heat provided by the heater layer throughout the baseplate. The baseplate includes a first material that has a first coefficient of thermal expansion (CTE) and a first thermal conductivity. The heat spreader includes a second material that has a second CTE and a second thermal conductivity greater than the first thermal conductivity.