Embodiments disclosed herein include a modular microwave source array. In an embodiment, a housing assembly for the source array comprises a first conductive layer, wherein the first conductive layer comprises a first coefficient of thermal expansion (CTE), and a second conductive layer over the first conductive layer, wherein the second conductive layer comprises a second CTE that is different than the first CTE. In an embodiment, the housing assembly further comprises a plurality of openings through the housing assembly, where each opening passes through the first conductive layer and the second conductive layer.

A microwave plasma source radiating a microwave in a chamber of a plasma processing apparatus to generate surface wave plasma includes a microwave output unit configured to generate and output a microwave, a microwave supply unit configured to transmit the microwave output from the microwave output unit, and a microwave radiation member configured as a ceiling wall of the chamber and configured to radiate the microwave supplied from the microwave supply unit into the chamber. The microwave supply unit includes microwave introduction mechanisms provided along a circumferential direction, thereby introducing the microwave to the microwave radiation member. The microwave radiation member includes slot antennas having slots through which the microwave is radiated and a microwave transmission member. The slots are provided to form a circular shape as a whole. The microwave transmission member provided to form a circular ring shape.

A plasma chemical vapor deposition device includes a chamber, a first conductor having an elongated shape, a second conductor having a tubular shape, a high-frequency output device, and a direct-current power supply. A first connecting portion of the first conductor with the high-frequency output device and a second connecting portion of the first conductor with the direct-current power supply are both placed outside the chamber. A distance from one end of the first conductor to the first connecting portion is shorter than a distance from the one end of the first conductor to the second connecting portion. An impedance change portion is provided between the first connecting portion and the second connecting portion in the first conductor, the impedance change portion having an impedance different from an impedance between the one end of the first conductor and the first connecting portion.

Provided is a film forming apparatus including a placement stage; a processing container that defines a processing chamber which accommodates the placement stage and includes a first region and a second region; a gas supply section that supplies a precursor gas to the first region; and a plasma generation section that generates plasma of a reactive gas in the second region. The plasma generation section includes: at least one waveguide that defines a wave guiding path above the placement stage and above the second region, a microwave generator connected to the at least one waveguide, and a plurality of protrusions made of a dielectric material. The protrusions pass through a plurality of openings formed in a lower conductive part of the at least one waveguide to extend into the second region. The protrusions are arranged in a radial direction with respect an axis of the placement stage.

A deposition apparatus and a method are provided. A method includes placing a substrate over a platform in a chamber of a deposition system. A precursor material is introduced into the chamber. A first gas curtain is generated in front of a first electromagnetic (EM) radiation source coupled to the chamber. A plasma is generated from the precursor material in the chamber, wherein the plasma comprises dissociated components of the precursor material. The plasma is subjected to a first EM radiation from the first EM radiation source. The first EM radiation further dissociates the precursor material. A layer is deposited over the substrate. The layer includes a reaction product of the dissociated components of the precursor material.

The present disclosure relates to an elementary device for producing a plasma. The elementary device includes a coaxial applicator of microwave power that includes a conductive central core, a conductive external shield surrounding the central core, a medium located between the central core and the shield to propagate microwave energy, and an insulating body. The elementary device further includes a system to couple to a microwave generator and is disposed at the shield. The shield has a proximal end plugged with the insulating body made of dielectric material that is transparent to the microwave energy. The insulating body has an external surface configured to contact and excite a gas located in the interior of a chamber. The insulating body extends exterior wise from the shield and its external surface is nonplanar and protrudes from the shield. The outside diameter of the body decreases from the shield to its tip.

A plasma processing apparatus includes: a chamber; a substrate support provided in the chamber; a bias power supply that supplies an electrical bias energy to an electrode of the substrate support; a matching box including a matching circuit; a radio-frequency power supply that supplies a radio-frequency power having a variable frequency into the chamber through the matching box, and adjusts the frequency of the radio-frequency power in each of a plurality of phase periods within the cycle of the electrical bias energy; a sensor that detects an electrical signal reflecting a deviation of a load impedance of the radio-frequency power supply from a matching state; and a filter that generates a filtered signal by removing and an intermodulation distortion component of the radio-frequency power and the electrical bias energy from the electrical signal in each of the plurality of phase periods.

A processing system is disclosed, having a power transmission element with an interior cavity that propagates electromagnetic energy proximate to a continuous slit in the interior cavity. The continuous slit forms an opening between the interior cavity and a substrate processing chamber. The electromagnetic energy may generate an alternating charge in the continuous slit that enables the generation of an electric field that may propagate into the processing chamber. The electric field may interact with process gas in the processing chamber to generate plasma for treating the substrate. The interior cavity may be isolated from the process chamber by a dielectric component that covers the continuous slit. The power transmission element may be used to control plasma density within the process chamber, either by itself or in combination with other plasma sources.

A deposition apparatus and a method are provided. A method includes placing a substrate over a platform in a chamber of a deposition system. A precursor material is introduced into the chamber. A first gas curtain is generated in front of a first electromagnetic (EM) radiation source coupled to the chamber. A plasma is generated from the precursor material in the chamber, wherein the plasma comprises dissociated components of the precursor material. The plasma is subjected to a first EM radiation from the first EM radiation source. The first EM radiation further dissociates the precursor material. A layer is deposited over the substrate. The layer includes a reaction product of the dissociated components of the precursor material.

Embodiments disclosed herein include a remote plasma source. In an embodiment, the remote plasma source comprises a housing where a fluidic channel passes from a first end to a second end of the housing. In an embodiment, an applicator intersects the fluidic channel. In an embodiment, the applicator comprises a dielectric body, and a pin inserted in a hole in the dielectric body.