Embodiments disclosed herein include a housing for a source array. In an embodiment, the housing comprises a conductive body, where the conductive body comprises a first surface and a second surface opposite from the first surface. In an embodiment a plurality of openings are formed through the conductive body and a channel is disposed into the second surface of the conductive body. In an embodiment, a cover is over the channel, and the cover comprises first holes that pass through a thickness of the cover. In an embodiment, the housing further comprises a second hole through a thickness of the conductive body. In an embodiment, the second hole intersects with the channel.

Embodiments disclosed herein include a housing for a source assembly. In an embodiment, the housing comprises a conductive body with a first surface and a second surface opposite from the first surface, and a plurality of openings through a thickness of the conductive body between the first surface and the second surface. In an embodiment, the housing further comprises a channel into the first surface of the conductive body, and a cover over the channel. In an embodiment, a first stem over the cover extends away from the first surface, and a second stem over the cover extends away from the first surface. In an embodiment, the first stem and the second stem open into the channel.

A microwave plasma device includes a treatment space and a number of two or more microwave semiconductors. The microwave semiconductors are attached to the treatment space in such a way that the microwaves of a microwave semiconductor only interfere with the microwaves of other microwave semiconductors when in the treatment space.

Plasma source assemblies, gas distribution assemblies including the plasma source assembly and methods of generating plasma are described. The plasma source assemblies include a powered electrode with a ground electrode adjacent a first side and a dielectric adjacent a second side. A first microwave generator is electrically coupled to the first end of the powered electrode through a first feed and a second microwave generator is electrically coupled to the second end of the powered electrode through a second feed.

A method of forming a graphene structure includes providing a substrate to be processed and forming a graphene structure on a surface of the substrate to be processed through a plasma CVD using plasma of a processing gas including a carbon-containing gas and an oxidizing gas in a state in which the surface of the substrate to be processed does not have a catalytic function.

A stage includes an electrostatic chuck that supports a substrate and an edge ring; and a base that supports the electrostatic chuck. The electrostatic chuck includes a first region having a first upper surface and supports the substrate placed on the first upper surface; a second region having a second upper surface, provided integrally around the first region, and supports the edge ring placed on the second upper surface; a first electrode provided in the first region to apply a DC voltage; a second electrode provided in the second region to apply a DC voltage, and a third electrode to apply a bias power.

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 substrate processing device capable of preventing deformation of a substrate during a process includes a substrate supporting unit having a contact surface that comes into contact with an edge of a substrate to be processed, wherein the substrate supporting unit includes a protruding (e.g. embossed) structure protruding from a base to support deformation from the inside of the edge of the substrate to be processed.

Embodiments disclosed herein include a high-frequency emission module. In an embodiment, the high-frequency emission module comprises a solid state high-frequency power source, an applicator for propagating high-frequency electromagnetic radiation from the power source, and a thermal break coupled between the power source and the applicator. In an embodiment, the thermal break comprises a substrate, a trace on the substrate, and a ground plane.

Systems and methods of forming a thin film on substrate includes positioning the substrate in a chamber; generating, via a uniform microwave field generator, a microwave field around the substrate; and guiding radicals into the chamber so that plasma is generated about the substrate to form the thin film on the substrate.