Some embodiments include a thermal management system for a nanosecond pulser. In some embodiments, the thermal management system may include a switch cold plates coupled with switches, a core cold plate coupled with one or more transformers, resistor cold plates coupled with resistors, or tubing coupled with the switch cold plates, the core cold plates, and the resistor cold plates. The thermal management system may include a heat exchanger coupled with the resistor cold plates, the core cold plate, the switch cold plate, and the tubing. The heat exchanger may also be coupled with a facility fluid supply.

A plasma processing apparatus includes a stage for supporting a target object in a chamber defined by a chamber body. The stage includes a lower electrode, an electrostatic chuck provided on the lower electrode, heaters provided in the electrostatic chuck, and terminals electrically connected to the heaters. A conductor pipe electrically connects a high frequency power supply and the lower electrode and extends from the lower electrode to the outside of the chamber body. Power supply lines supply power from a heater controller to the heaters. Filters partially forming the power supply lines prevent the inflow of high frequency power from the heaters to the heater controller. The power supply lines include wirings which respectively connect the terminals and the filters and extend to the outside of the chamber body through an inner bore of the conductor pipe.

Plasma processing equipment includes a chuck stage for supporting a wafer and including a lower electrode, an upper electrode disposed on the chuck stage, an AC power supply which applies first to third signals having different magnitudes of frequencies to the upper electrode or the lower electrode, a dielectric ring which surrounds the chuck stage, an edge electrode located within the dielectric ring, and a resonance circuit connected to the edge electrode. The resonance circuit includes a filter circuit which allows only the third signal among the first to third signals to pass, and a series resonance circuit connected in series with the filter circuit and having a first coil and a first variable capacitor connected in series and grounded.

A plasma processing apparatus may include a lower electrode supporting a wafer; a focus ring surrounding an edge of the lower electrode and having a ring shape; and an edge ring disposed in a position lower than a position of the focus ring. The focus ring may include a lower region and an upper region disposed on the lower region, and the upper region increases in electrical conductivity as the upper region is closer to the lower region.

A method of making nanoparticles including a semiconducting nitride is provided. The method includes reacting precursors in a gas phase to form the nanoparticles including the semiconducting nitride. The precursors include at least one of a gallium (Ga) precursor or an indium (In) precursor and a nitrogen (N) precursor. The semiconducting nitride is In.sub.1−xGa.sub.xN, where 0≤x≤1. Structures that include the nanoparticles and systems for making the nanoparticles are also provided.

Plasma processing equipment includes a chuck stage for supporting a wafer and including a lower electrode, an upper electrode disposed on the chuck stage, an AC power supply which applies first to third signals having different magnitudes of frequencies to the upper electrode or the lower electrode, a dielectric ring which surrounds the chuck stage, an edge electrode located within the dielectric ring, and a resonance circuit connected to the edge electrode. The resonance circuit includes a filter circuit which allows only the third signal among the first to third signals to pass, and a series resonance circuit connected in series with the filter circuit and having a first coil and a first variable capacitor connected in series and grounded.

Embodiments of the present disclosure generally relate to apparatuses for reducing particle contamination on substrates in a plasma processing chamber. In one or more embodiments, an edge ring is provided and includes a top surface, a bottom surface opposite the top surface and extending radially outward, an outer vertical wall extending between and connected to the top surface and the bottom surface, an inner vertical wall opposite the outer vertical wall, an inner lip extending radially inward from the inner vertical wall, and an inner step disposed between and connected to the inner wall and the bottom surface. During processing, the edge ring shifts the high plasma density zone away from the edge area of the substrate to avoid depositing particles on the substrate when the plasma is de-energized.

Provided is a filter device including a plurality of coils, a plural of capacitors, and a frame. The coils constitute a plurality of coil groups. Each coil group includes two or more coils. The two or more coils in each coil group are provided such that respective windings of the two or more coils extend spirally about a central axis and respective turns of the two or more coils are sequentially and repeatedly arranged in an axial direction in which the central axis extends. The coil groups are provided coaxially with the central axis. A pitch between the respective turns of the two or more coils of any one coil group among the coil groups is larger than a pitch between the respective turns of the two or more coils of the coil group provided inside the one coil group among the coil groups.

Described herein is a technique capable of capable of uniformly processing a surface of a substrate even when an inductive coupling type substrate processing apparatus is used. According to one aspect of the technique, there is provided a substrate processing apparatus including: a process chamber in which a substrate is processed; a gas supply part configured to supply a gas into the process chamber; a high frequency power supply part configured to supply a high frequency power; a plasma generator including a resonance coil wound on a side of the process chamber, the plasma generator configured to generate a plasma in the process chamber when the high frequency power is supplied to the resonance coil; and a substrate support on which the substrate is placed such that a horizontal center position of the substrate in the process chamber does not overlap with a horizontal center position of the resonance coil.

Embodiments of the present disclosure generally relate to methods for forming epitaxial layers on a semiconductor device. In one or more embodiments, methods include removing oxides from a substrate surface during a cleaning process, flowing a processing reagent containing a silicon source and exposing the substrate to the processing reagent during an epitaxy process, and stopping the flow of the processing reagent. The method also includes flowing a purging gas and pumping residues from the processing system, stopping the flow of the purge gas, flowing an etching gas and exposing the substrate to the etching gas. The etching gas contains hydrogen chloride and at least one germanium and/or chlorine compound. The method further includes stopping the flow of the at least one compound while continuing the flow of the hydrogen chloride and exposing the substrate to the hydrogen chloride and stopping the flow of the hydrogen chloride.