Abstract: A system and method including a processing device. The processing device receives data including one or more plasma exposure durations of a plasma process. The plasma exposure duration are associated with a set of controlled elements. The processing device causes a each set of controlled elements to switch between a first mode of operation and a second mode of operation. Each set of controlled elements expose appropriate portion of a substrate to the plasma related fluxes. The first set of controlled elements process the substrate at an increased rate while operating in the first mode of operation relative to the second mode of operation. The processing device causes each set of controlled elements to operate in the first mode of operation for the appropriate time duration based on the received plasma exposure duration data.

Abstract: Embodiments of the present disclosure generally relate to inductively coupled plasma sources and plasma processing apparatus. In at least one embodiment, plasma source includes a first sidewall and a gas injection insert defining a plasma source interior volume. The gas injection insert includes a peripheral gas injection port, a second sidewall disposed concentric with the first sidewall, and a center gas injection port. The plasma source includes a first induction coil disposed proximate the first sidewall and disposed around the first sidewall. The plasma source includes a first radio frequency power generator coupled with the first induction coil. The plasma source includes a second induction coil disposed proximate the second sidewall and disposed around the second sidewall. The plasma source includes a second radio frequency power generator coupled with the second induction coil.

Abstract: Embodiments of the present disclosure generally relate to the fabrication of integrated circuits and to apparatus for use within a substrate processing chamber to improve film thickness uniformity. More specifically, the embodiments of the disclosure relate to an edge ring. The edge ring may include an overhang ring.

Abstract: A system and method including a processing device. The processing device receives data including one or more plasma exposure durations of a plasma process. The plasma exposure duration are associated with a set of controlled elements. The processing device causes a each set of controlled elements to switch between a first mode of operation and a second mode of operation. Each set of controlled elements expose appropriate portion of a substrate to the plasma related fluxes. The first set of controlled elements process the substrate at an increased rate while operating in the first mode of operation relative to the second mode of operation. The processing device causes each set of controlled elements to operate in the first mode of operation for the appropriate time duration based on the received plasma exposure duration data.

Abstract: A plasma generating component for a process chamber includes a first pair of linear electrodes. Each electrode of the first pair of linear electrodes extends from a first edge of a plasma generating region of the plasma generating component to a second edge of the plasma generating region of the plasma generating component. Electrodes of the first pair of linear electrodes are substantially parallel. The plasma generating component further includes a second pair of linear electrodes, substantially parallel to the first pair of linear electrodes. The plasma generating component further includes a dielectric support to which the first pair of linear electrodes and the second pair of linear electrodes are secured.

Abstract: A system including a control plate disposed within a processing chamber. The control plate includes a set of plasma elements designed to independently expose a substrate disposed within the processing chamber to plasma related fluxes. The control plate is designed to independently activate the set of plasma elements. When activated the associated plasma elements expose the substrate to the plasma related fluxes and when not activated the associated plasma elements prevent exposure of the substrate to the plasma related fluxes. The control plate is designed to perform individual time-dependent activation of the set of plasma elements to selectively expose the substrate to the plasma related fluxes.

Abstract: A system and method including a processing device. The processing device receives data including a first set of plasma exposure values each associated with a respective plasma element of a plurality of plasma elements designed to generate plasma related fluxes. The processing device causes a plasma controller to activate the set of plasma elements based on the data to expose a substrate to the plasma related fluxes generated by the set of plasma elements during a plasma process. Each respective plasma element of the set of plasma elements is activated for a duration based on a respective plasma exposure value from the first plurality of plasma exposure values that is associated with the respective plasma element.

Abstract: Embodiments of the present disclosure generally relate to inductively coupled plasma sources, plasma processing apparatus, and independent temperature control of plasma processing. In at least one embodiment, a method includes introducing a process gas into a gas injection channel and generating an inductively coupled plasma within the gas injection channel. The plasma includes at least one radical species selected from oxygen, nitrogen, hydrogen, NH and helium. The method includes delivering the plasma from the plasma source to a process chamber coupled therewith by flowing the plasma through a separation grid between the plasma source and a substrate. The method includes processing the substrate. Processing the substrate includes contacting the plasma including the at least one radical species with a first side of the substrate facing the separation grid and heating the substrate using a plurality of lamps located on a second side of the substrate opposite the separation grid.

Abstract: A system, method, and apparatus for processing substrates. A plasma processing system includes a processing chamber and a support structure disposed within the processing chamber. The support structure forms a set of ducts. The plasma processing system further includes a plurality of plasma generation cells disposed within corresponding ducts of the set of ducts. The plasma generation cells are configured to be selectively activated or deactivated. The plasma generating structure supplies plasma related fluxes to a region of the processing chamber responsive to being activated. The plasma processing system further includes a network of electrical connectors coupled to each of the plurality of plasma generation cells. The network of electrical connectors are configured to supply electrical signals that selectively activate or deactivate individual plasma generation cells.

Abstract: A system, method, and apparatus for processing substrates. A plasma generation assembly includes a support structure configured to be disposed within a processing chamber, the support structure forming a set of ducts. The plasma generation assembly further includes a plasma generation cell selectively removable from and selectively replaceable within one of set of ducts. The plasma generation cell includes a dielectric barrier discharge (DBD) structure. The DBD structure includes a set of electrodes disposed along a first dielectric surface and covered by a second dielectric layer. The DBD structure is configured to initiate plasma discharge within the processing chamber. The DBD structure further includes electrical terminals coupled the DBD structure with an electric driving network.

Abstract: A method of manufacturing a dielectric barrier discharge (DBD) structure includes forming a patterned electrode layer around an outer perimeter of a substrate composed of a dielectric material. The patterned electrode layer includes multiple electrodes around the outer perimeter of the substrate and gaps between adjacent electrodes. The method further includes depositing a dielectric layer over at least a first region of the patterned electrode layer to form a DBD region of the DBD structure.

Abstract: The present technology encompasses plasma sources including a first plate defining a first plurality of apertures arranged in a first set of rows. The first plate may include a first set of electrodes extending along a separate row of the first set of rows. The plasma sources may include a second plate defining a second plurality of apertures arranged in a second set of rows. The second plate may include a second set of electrodes extending along a separate row of the second set of rows. Each aperture of the second plurality of apertures may be axially aligned with an aperture of the first plurality of apertures. The plasma sources may include a third plate positioned between the first plate and the second plate. The third plate may define a third plurality of apertures.

Abstract: A system, method, and apparatus for processing substrates. A plasma processing system includes a processing chamber having a chamber body having walls with a first material enclosing an interior volume. The plasma processing system further includes a plasma source designed to expose a substrate disposed within the processing chamber to plasma related fluxes. The first material has a first set of recombination coefficients associated with the plasma related fluxes. The plasma processing system further includes a second material disposed along a first region of the chamber body, the first material having a second set of plasma recombination coefficients associated with the plasma related fluxes. The second set of plasma recombination coefficients is different that the first set of plasma recombination coefficients.

Abstract: Embodiments of the present disclosure generally relate to inductively coupled plasma sources and plasma processing apparatus. In at least one embodiment, plasma source includes a first sidewall and a gas injection insert defining a plasma source interior volume. The gas injection insert includes a peripheral gas injection port, a second sidewall disposed concentric with the first sidewall, and a center gas injection port. The plasma source includes a first induction coil disposed proximate the first sidewall and disposed around the first sidewall. The plasma source includes a first radio frequency power generator coupled with the first induction coil. The plasma source includes a second induction coil disposed proximate the second sidewall and disposed around the second sidewall. The plasma source includes a second radio frequency power generator coupled with the second induction coil.

Abstract: A system and method including a processing device. The processing device receives data including one or more plasma exposure durations of a plasma process. The plasma exposure duration are associated with a set of controlled elements. The processing device causes a each set of controlled elements to switch between a first mode of operation and a second mode of operation. Each set of controlled elements expose appropriate portion of a substrate to the plasma related fluxes. The first set of controlled elements process the substrate at an increased rate while operating in the first mode of operation relative to the second mode of operation. The processing device causes each set of controlled elements to operate in the first mode of operation for the appropriate time duration based on the received plasma exposure duration data.

Abstract: Devices, assemblies, and system including a plasma delivery device comprising a memory element that stores a first state or a second state. The memory element is configured to receive a first signal that causes the memory element to change between the first state and the second state. The plasma delivery device further includes a switch coupled to the memory element. The switch is configured to change between an open configuration and a closed configuration. The plasma delivery device further comprises a plasma emitter coupled to the switch. The plasma emitter is configured to be selectively activated and deactivated. The plasma emitter supplies plasma related fluxes to an environment proximate the plasma delivery device responsive to being activated. The plasma emitter is configured to receive a second signal that activates the plasma emitter based on the open configuration or the closed configuration of the switch.

Abstract: A system including a control plate disposed within a processing chamber. The control plate includes a set of plasma elements designed to independently expose a substrate disposed within the processing chamber to plasma related fluxes. The control plate is designed to independently activate the set of plasma elements. When activated the associated plasma elements expose the substrate to the plasma related fluxes and when not activated the associated plasma elements prevent exposure of the substrate to the plasma related fluxes. The control plate is designed to perform individual time-dependent activation of the set of plasma elements to selectively expose the substrate to the plasma related fluxes.

Abstract: A system and method including a processing device. The processing device receives data including a first set of plasma exposure values each associated with a respective plasma element of a plurality of plasma elements designed to generate plasma related fluxes. The processing device causes a plasma controller to activate the set of plasma elements based on the data to expose a substrate to the plasma related fluxes generated by the set of plasma elements during a plasma process. Each respective plasma element of the set of plasma elements is activated for a duration based on a respective plasma exposure value from the first plurality of plasma exposure values that is associated with the respective plasma element.

Abstract: Embodiments of the present disclosure generally relate to inductively coupled plasma sources, plasma processing apparatus, and independent temperature control of plasma processing. In at least one embodiment, a method includes introducing a process gas into a gas injection channel and generating an inductively coupled plasma within the gas injection channel. The plasma includes at least one radical species selected from oxygen, nitrogen, hydrogen, NH and helium. The method includes delivering the plasma from the plasma source to a process chamber coupled therewith by flowing the plasma through a separation grid between the plasma source and a substrate. The method includes processing the substrate. Processing the substrate includes contacting the plasma including the at least one radical species with a first side of the substrate facing the separation grid and heating the substrate using a plurality of lamps located on a second side of the substrate opposite the separation grid.