Abstract: Exemplary support assemblies may include a top puck defining a substrate support surface, where the top puck is also characterized by a height. The assemblies may include a stem coupled with the top puck on a second surface of the top puck opposite the substrate support surface. The assemblies may include an RF electrode embedded within the top puck proximate the substrate support surface. The assemblies may include a heater embedded within the top puck. The assemblies may also include a ground shield embedded within the top puck. The ground shield may be characterized by an inner region extending radially through the top puck. The ground shield may further be characterized by an outer region extending perpendicular to the inner region.

Abstract: Methods of monitoring a plasma while processing a semiconductor substrate are described. In embodiments, the methods include determining the difference in power between the power delivered from the plasma power supply and the power received by the plasma in a substrate processing chamber. The power received may be determined using a V/I sensor positioned after the matching circuit. The power reflected or the power lost is the difference between the delivered power and the received power. The process may be terminated by removing the delivered power if the reflected power is above a setpoint. The VRF may further be fourier transformed into frequency space and compared to the stored fourier transform of a healthy plasma process. Missing frequencies from the VRF fourier transform may independently or further indicate an out-of-tune plasma process and the process may be terminated.

Abstract: Exemplary systems according to embodiments of the present technology include a housing that defines a process chamber and a waveguide cavity. A first conductive plate is disposed within the housing. The system also includes a second conductive plate positioned within the housing and at least partially defining the waveguide cavity. The second conductive plate is vertically translatable within the housing to adjust a distance between the first conductive plate and the second conductive plate to affect modes of electromagnetic radiation propagating within the waveguide cavity. The systems also include one or more electronics sets that are configured to transmit the electromagnetic radiation into the waveguide cavity to produce plasma from at least one process gas delivered within the process chamber.

Abstract: Exemplary apparatuses for centering and/or leveling a pedestal of a processing chamber may include a mounting block having a central axis, a set of first gauges mounted on the mounting block, and a set of second gauges mounted on the mounting block. The set of second gauges may be mounted substantially perpendicular to the set of first gauges. The plurality of first gauges may be configured to obtain measurements indicative of a degree of parallelism between a gas distribution plate of the processing chamber and the pedestal. The plurality of second gauges may be configured to obtain measurements indicative of a degree of axial alignment of a ring member of the processing chamber and the pedestal. The exemplary apparatuses may be used for centering and/or leveling the pedestal under vacuum.

Abstract: Exemplary support assemblies may include a top puck defining a substrate support surface, where the top puck is also characterized by a height. The assemblies may include a stem coupled with the top puck on a second surface of the top puck opposite the substrate support surface. The assemblies may include an RF electrode embedded within the top puck proximate the substrate support surface. The assemblies may include a heater embedded within the top puck. The assemblies may also include a ground shield embedded within the top puck. The ground shield may be characterized by an inner region extending radially through the top puck. The ground shield may further be characterized by an outer region extending perpendicular to the inner region.

Abstract: Exemplary apparatuses for centering and/or leveling a pedestal of a processing chamber may include a mounting block having a central axis, a set of first gauges mounted on the mounting block, and a set of second gauges mounted on the mounting block. The set of second gauges may be mounted substantially perpendicular to the set of first gauges. The plurality of first gauges may be configured to obtain measurements indicative of a degree of parallelism between a gas distribution plate of the processing chamber and the pedestal. The plurality of second gauges may be configured to obtain measurements indicative of a degree of axial alignment of a ring member of the processing chamber and the pedestal. The exemplary apparatuses may be used for centering and/or leveling the pedestal under vacuum.

Abstract: A system includes a process chamber, a housing that defines a waveguide cavity, and a first conductive plate within the housing. The first conductive plate faces the process chamber. The system also includes one or more adjustment devices that can adjust at least a position of the first conductive plate, and a second conductive plate, coupled with the housing, between the waveguide cavity and the process chamber. Electromagnetic radiation can propagate from the waveguide cavity into the process chamber through apertures in the second conductive plate. The system also includes a dielectric plate that seals off the process chamber from the waveguide cavity, and one or more electronics sets that transmit the electromagnetic radiation into the waveguide cavity. A plasma forms when at least one process gas is within the chamber, and the electromagnetic radiation propagates into the process chamber from the waveguide cavity.

Abstract: A system includes a process chamber, a housing that defines a waveguide cavity, and a first conductive plate within the housing. The first conductive plate faces the process chamber. The system also includes one or more adjustment devices that can adjust at least a position of the first conductive plate, and a second conductive plate, coupled with the housing, between the waveguide cavity and the process chamber. Electromagnetic radiation can propagate from the waveguide cavity into the process chamber through apertures in the second conductive plate. The system also includes a dielectric plate that seals off the process chamber from the waveguide cavity, and one or more electronics sets that transmit the electromagnetic radiation into the waveguide cavity. A plasma forms when at least one process gas is within the chamber, and the electromagnetic radiation propagates into the process chamber from the waveguide cavity.

Abstract: Systems and methods may be used to enact plasma filtering. Exemplary processing chambers may include a showerhead. The processing chambers may include a substrate support. The processing chambers may include a power source electrically coupled with the substrate support and configured to provide power to the substrate support to produce a bias plasma within a processing region defined between the showerhead and the substrate support. The processing systems may include a plasma screen coupled with the substrate support and configured to substantially eliminate plasma leakage through the plasma screen. The plasma screen may be coupled with electrical ground.

Abstract: Methods of monitoring a plasma while processing a semiconductor substrate are described. In embodiments, the methods include determining the difference in power between the power delivered from the plasma power supply and the power received by the plasma in a substrate processing chamber. The power received may be determined using a V/I sensor positioned after the matching circuit. The power reflected or the power lost is the difference between the delivered power and the received power. The process may be terminated by removing the delivered power if the reflected power is above a setpoint. The VRF may further be fourier transformed into frequency space and compared to the stored fourier transform of a healthy plasma process. Missing frequencies from the VRF fourier transform may independently or further indicate an out-of-tune plasma process and the process may be terminated.

Abstract: A system includes a process chamber, a housing that defines a waveguide cavity, and a first conductive plate within the housing. The first conductive plate faces the process chamber. The system also includes one or more adjustment devices that can adjust at least a position of the first conductive plate, and a second conductive plate, coupled with the housing, between the waveguide cavity and the process chamber. Electromagnetic radiation can propagate from the waveguide cavity into the process chamber through apertures in the second conductive plate. The system also includes a dielectric plate that seals off the process chamber from the waveguide cavity, and one or more electronics sets that transmit the electromagnetic radiation into the waveguide cavity. A plasma forms when at least one process gas is within the chamber, and the electromagnetic radiation propagates into the process chamber from the waveguide cavity.

Abstract: Systems and methods for testing semiconductor wafers using a wafer translator are disclosed herein. In one embodiment, an apparatus for testing semiconductor dies includes a semiconductor wafer translator having a wafer-side positioned to face toward a device under test, and an inquiry-side facing away from the wafer-side. The apparatus also includes a flexible arm peripherally connected to the wafer translator, and an evacuation opening within the flexible arm or within the wafer translator. The evacuation opening is open to a flow of a gas in a first position of the flexible arm, and closed to a flow of the gas in a second position of the flexible arm.

Abstract: Systems and methods for testing semiconductor wafers using a wafer translator are disclosed herein. In one embodiment, an apparatus for testing semiconductor dies on a wafer includes a wafer translator having a wafer-side facing toward the wafer, and an inquiry-side facing away from the wafer-side. The wafer has an active side facing the translator. The apparatus includes a peripheral seal configured to seal a space between the wafer translator and the wafer, and a valve in a fluidic communication with the space between the wafer translator and the wafer.