A thruster system for use in a spacecraft includes a microwave source, a resonant cavity coupled to the microwave source, wherein the microwave source is configured to generate a standing wave field in the resonant cavity, a nozzle provided at one end of the resonant cavity; and at least one injector configured to inject propellant into the resonant cavity so as to create a rotating circumferential flow. The standing wave field raises a temperature of the injected propellant to provide thrust by way of a hot gas exiting the resonant cavity via the nozzle.

The invention relates to a microwave plasma-assisted deposition modular reactor for manufacturing synthetic diamond. The reactor has at least three modulation elements selected from: a crown adapted to be positioned between a first enclosure part and a second enclosure part; a substrate holder module mobile in vertical translation and in rotation, in contact with a quarter-wave and including at least one fluid cooling system; a tray mobile in vertical translation in order to change the shape and volume of the resonant cavity and including through openings allowing the gases to pass; a gas distribution module, including a removable gas distribution plate comprising an inner surface, an outer surface, and a plurality of gas distribution nozzles forming channels between said surfaces capable of conducting a gas flow, and a support device connected to a cooling system and adapted to accommodate the removable gas distribution plate; and a substrate cooling control module including a removable thermal resistance gas injection device.

A portable, modular plasma source allows the production of an emission spectrometer by combination with a common portable fiber optic spectrograph by channeling emitted light through a fiber optic coupling communicating light from the plasma source to the portable fiber optic spectrograph.

Embodiments include a plasma processing tool that includes a processing chamber, and a plurality of modular microwave sources coupled to the processing chamber. In an embodiment, the plurality of modular microwave sources include an array of applicators that are positioned over a dielectric body that forms a portion of an outer wall of the processing chamber. The array of applicators may be coupled to the dielectric body. Additionally, the plurality of modular microwave sources may include an array of microwave amplification modules. In an embodiment, each microwave amplification module may be coupled to at least one of the applicators in the array of applicators. According to an embodiment, the dielectric body be planar, non-planar, symmetric, or non-symmetric. In yet another embodiment, the dielectric body may include a plurality of recesses. In such an embodiment, at least one applicator may be positioned in at least one of the recesses.

Embodiments include a modular microwave source. In an embodiment, the modular microwave source comprises a voltage control circuit, a voltage controlled oscillator, where an output voltage from the voltage control circuit drives oscillation in the voltage controlled oscillator. The modular microwave source may also include a solid state microwave amplification module coupled to the voltage controlled oscillator. In an embodiment, the solid state microwave amplification module amplifies an output from the voltage controlled oscillator. The modular microwave source may also include an applicator coupled to the solid state microwave amplification module, where the applicator is a dielectric resonator.

A plasma processing apparatus includes a chamber, a mounting table for mounting thereon a target object in the chamber, a plasma source configured to introduce microwaves into the chamber through a ceiling wall of the chamber and generate a surface wave plasma in the chamber, a first gas introduction unit for introducing a first gas into the chamber from the ceiling wall, and a second gas introduction unit for introducing a second gas into the chamber from a location between the ceiling wall and the mounting table. The second gas introduction unit includes a ring-shaped member having a plurality of gas injection holes and provided at a predetermined height position between the ceiling wall and the mounting table, and a leg part which connects the ceiling wall and the ring-shaped member. The second gas is supplied to the ring-shaped member through the leg part.

A plasma processing apparatus includes: a processing chamber in which a sample is subjected to plasma processing, including, at an upper side therein, a dielectric plate, through which microwaves are transmitted; a radio frequency power supply which supplies radio frequency power for the microwaves; a cavity resonator which resonates microwaves transmitted from the radio frequency power supply through a waveguide and is placed above the dielectric plate; and a magnetic field forming mechanism which forms a magnetic field in the processing chamber. The plasma processing apparatus further includes: a ring-shaped conductor placed inside the cavity resonator; and a circular conductor which is placed inside the cavity resonator and placed in an opening at the center of the ring-shaped conductor.

A thruster system for use in a spacecraft includes a microwave source, a resonant cavity coupled to the microwave source, wherein the microwave source is configured to generate a standing wave field in the resonant cavity, a nozzle provided at one end of the resonant cavity; and at least one injector configured to inject propellant into the resonant cavity so as to create a rotating circumferential flow. The standing wave field raises a temperature of the injected propellant to provide thrust by way of a hot gas exiting the resonant cavity via the nozzle.

Embodiments include a modular microwave source. In an embodiment, the modular microwave source comprises a voltage control circuit, a voltage controlled oscillator, where an output voltage from the voltage control circuit drives oscillation in the voltage controlled oscillator. The modular microwave source may also include a solid state microwave amplification module coupled to the voltage controlled oscillator. In an embodiment, the solid state microwave amplification module amplifies an output from the voltage controlled oscillator. The modular microwave source may also include an applicator coupled to the solid state microwave amplification module, where the applicator is a dielectric resonator.

A microwave plasma reactor for manufacturing synthetic diamond material via chemical vapour deposition, the microwave plasma reactor comprising: a plasma chamber defining a resonant cavity for supporting a primary microwave resonance mode having a primary microwave resonance mode frequency f; a plurality of microwave sources coupled to the plasma chamber for generating and feeding microwaves having a total microwave power P into the plasma chamber; a gas flow system for feeding process gases into the plasma chamber and removing them therefrom; and a substrate holder disposed in the plasma chamber and comprising a supporting surface for supporting a substrate on which the synthetic diamond material is to be deposited in use, wherein the plurality of microwave sources are configured to couple at least 30% of the total microwave power P into the plasma chamber in the primary microwave resonance mode frequency f, and wherein at least some of the plurality of microwave sources are solid state microwave sources.