Abstract: A radio frequency (RF) generator system includes first and second RF power sources, each RF power source applying a respective RF signal and second RF signal to a load. The first RF signal is applied in accordance with the application of the second RF signal. The application of the first RF signal is synchronized to application of the second RF signal. The first RF signal may be amplitude modulated in synchronization with the second RF signal, and the amplitude modulation can include blanking of the first RF signal. A frequency offset may be applied to the first RF signal in synchronization with the second RF signal. A variable actuator associated with the first RF power source may be controlled in accordance with the second RF signal.

Abstract: Systems and methods for cleaning an edge ring pocket are described herein. One of the methods includes providing one or more process gases to a plasma chamber, supplying a low frequency (LF) radio frequency (RF) power to an edge ring that is located adjacent to a chuck of the plasma chamber. The LF RF power is supplied while the one or more process gases are supplied to the plasma chamber to maintain plasma within the plasma chamber. The supply of the LF RF power increases energy of plasma ions near the edge ring pocket to remove residue in the edge ring pocket. The LF RF power is supplied during the time period in which a substrate is not being processed within the plasma chamber.

Abstract: A method for optimizing delivery of power to a plasma chamber is described. The method includes dividing each cycle of a low frequency (LF) radio frequency generator (RFG) into multiple time intervals. During each of the time intervals, a frequency offset of a high frequency (HF) RFG is generated for which the delivery of power is maximized. The frequency offsets provide a substantially inverse relationship compared to a voltage signal of the LF RFG for each cycle of the voltage signal. The frequency offsets for the time intervals are multiples of the low frequency. The substantially inverse relationship facilitates an increase in the delivery of power to the electrode. A total range of the frequency offsets from a reference HF frequency over the LF RF cycle depends on a power ratio of power that is supplied by the LF RFG and power that is supplied by the HF RFG.

Abstract: First, second, third, and fourth radiofrequency (RF) signal generators generate first, second, third, and fourth RF signals, respectively, having first, second, third, and fourth frequencies, respectively. The second and third frequencies are different specified harmonics of the first frequency. The fourth frequency is at least two orders of magnitude larger than the first frequency. An impedance matching system controls impedances for the first, second, third, and fourth RF signal generators. A control module is programmed to control: A) a first phase difference between the first and second RF signals, B) a second phase difference between the first and third RF signals, C) a first voltage difference between the first and second RF signals, D) a second voltage difference between the first and third RF signals. The first and second phase differences and the first and second voltage differences collectively control a plasma sheath voltage as a function of time.

Abstract: A first radiofrequency signal generator is set to generate a low frequency signal. A second radiofrequency signal generator is set to generate a high frequency signal. An impedance matching system has a first input connected to an output of the first radiofrequency signal generator and a second input connected to an output of the second radiofrequency signal generator. The impedance matching system controls impedances at the outputs of the first and second radiofrequency signal generators. An output of the impedance matching system is connected to a radiofrequency supply input of a plasma processing system. A control module monitors reflected voltage at the output of the second radiofrequency signal generator. The control module determines when the reflected voltage indicates a change in impedance along a transmission path of the high frequency signal that is indicative of a particular process condition and/or event within the plasma processing system.

Abstract: A system having the low frequency RF generator is described. The low frequency RF has an operating frequency range between 10 kilohertz (kHz) and 330 kHz. The low frequency RF generator generates an RF signal. The system further includes an impedance matching circuit coupled to the low frequency RF generator for receiving the RF signal. The impedance matching circuit modifies an impedance of the RF signal to output a modified RF signal. The system includes a plasma chamber coupled to the RF generator for receiving the modified RF signal. The plasma chamber includes a chuck having a dielectric layer and a base metal layer. The dielectric layer is located on top of the base metal layer. The dielectric layer has a bottom surface, and the base metal layer has a top surface. The base metal layer has a porous plug and the bottom surface of the dielectric layer has a portion that is in contact with the porous plug.

Abstract: An RF signal supply system for plasma generation includes an RF signal generator, an impedance matching system, and a control module. The RF signal generator includes a control system. The impedance matching system has an input connected to an output of the RF signal generator, an output connected to a plasma processing system, a gamma control capacitor, and a frequency control capacitor. The control module is connected in data communication with each of the RF signal generator and the impedance matching system. The control module is programmed to transmit control signals to the impedance matching system based on corresponding data received from the control system of the RF signal generator, where the control signals direct control of the gamma control capacitor and the frequency control capacitor. The control module is also programmed to transmit data received from the impedance matching system to the control system of the RF signal generator.

Abstract: An impedance match housing is described. The impedance match housing includes an impedance matching circuit having an input that is coupled to a radio frequency (RF) generator. The impedance matching circuit has an output that is coupled to a first RF strap. The impedance match housing includes a uniformity control circuit coupled in parallel to a portion of the first RF strap to modify uniformity in a processing rate of a substrate when the substrate is processed within a plasma chamber.

Abstract: Systems and methods for controlling a plasma sheath characteristic are described. One of the methods includes determining a first value of the plasma sheath characteristic of a plasma sheath formed within a plasma chamber. The method further includes determining whether the first value of the plasma sheath characteristic is within a predetermined range from a preset value of the plasma sheath characteristic. The method also includes modifying a variable of a radio frequency (RF) generator coupled to the plasma chamber via an impedance matching circuit upon determining that the first value is not within the predetermined range from the preset value. The operation of modifying the variable of the RF generator is performed until it is determined that the first value of the plasma sheath characteristic is within the predetermined range from the preset value.

Abstract: A method for achieving a first uniformity level in a processing rate across a surface of a substrate is described. The method includes receiving the first uniformity level to be achieved across the surface of the substrate and identifying a first plurality of duty cycles associated with a first plurality of states based on the first uniformity level. The first plurality of states are of a variable of a first radio frequency (RF) signal. The method further includes controlling an RF generator to generate the first RF signal having the first plurality of duty cycles.

Abstract: A magnetic field sensor for measuring magnetic field of a current applied to a lower electrode defined within a plasma chamber includes a conductor element disposed along a length of a tubular housing. A plurality of slots is defined on one side of the tubular housing to expose the conductor element.

Abstract: An impedance match is described. The impedance match includes a housing having a bottom portion and a top portion. The bottom portion has match components and the top portion has an elongated body. A low frequency input is connected through the bottom portion of the housing, and the low frequency input is interconnected to a first set of capacitors and inductors. A high frequency input is connected through the bottom portion of the housing, and the high frequency input is interconnected to a second set of capacitors and inductors. An elongated strap extends between the bottom portion and the top portion of the housing. A lower portion of the elongated strap is coupled to the second set of capacitors and inductors and an upper portion of the elongated strap is connected to an RF rod at an end of the elongated body.

Abstract: An edge ring system comprising a substrate support configured to support a substrate during plasma processing and including a baseplate and an upper layer arranged on the baseplate. An edge ring support includes a first body and an electrostatic clamping electrode arranged in the first body. The edge ring support is arranged above the baseplate and radially outside of the substrate during processing. An edge ring includes a second body arranged on and electrostatically clamped to the edge ring support during plasma processing.

Abstract: A method for achieving uniformity in an etch rate is described. The method includes receiving a voltage signal from an output of a match, and determining a positive crossing and a negative crossing of the voltage signal for each cycle of the voltage signal. The negative crossing of each cycle is consecutive to the positive crossing of the cycle. The method further includes dividing a time interval of each cycle of the voltage signal into a plurality of bins. For one or more of the plurality of bins associated with the positive crossing and one or more of the plurality of bins associated with the negative crossing, the method includes adjusting a frequency of a radio frequency generator to achieve the uniformity in the etch rate.

Abstract: Systems and methods for cleaning an edge ring pocket are described herein. One of the methods includes providing one or more process gases to a plasma chamber, supplying a low frequency (LF) radio frequency (RF) power to an edge ring that is located adjacent to a chuck of the plasma chamber. The LF RF power is supplied while the one or more process gases are supplied to the plasma chamber to maintain plasma within the plasma chamber. The supply of the LF RF power increases energy of plasma ions near the edge ring pocket to remove residue in the edge ring pocket. The LF RF power is supplied during the time period in which a substrate is not being processed within the plasma chamber.

Abstract: A method for optimizing delivery of power to a plasma chamber is described. The method includes dividing each cycle of a low frequency (LF) radio frequency generator (RFG) into multiple time intervals. During each of the time intervals, a frequency offset of a high frequency (HF) RFG is generated for which the delivery of power is maximized. The frequency offsets provide a substantially inverse relationship compared to a voltage signal of the LF RFG for each cycle of the voltage signal. The frequency offsets for the time intervals are multiples of the low frequency. The substantially inverse relationship facilitates an increase in the delivery of power to the electrode. A total range of the frequency offsets from a reference HF frequency over the LF RF cycle depends on a power ratio of power that is supplied by the LF RFG and power that is supplied by the HF RFG.

Abstract: A method for optimizing delivery of power to a plasma chamber is described. The method includes dividing each cycle of a low frequency (LF) radio frequency generator (RFG) into multiple time intervals. During each of the time intervals, a frequency offset of a high frequency (HF) RFG is generated for which the delivery of power is maximized. The frequency offsets provide a substantially inverse relationship compared to a voltage signal of the LF RFG for each cycle of the voltage signal. The frequency offsets for the time intervals are multiples of the low frequency. The substantially inverse relationship facilitates an increase in the delivery of power to the electrode. A total range of the frequency offsets from a reference HF frequency over the LF RF cycle depends on a power ratio of power that is supplied by the LF RFG and power that is supplied by the HF RFG.

Abstract: A radio frequency (RF) generator system includes first and second RF power sources, each RF power source applying a respective RF signal and second RF signal to a load. The first RF signal is applied in accordance with the application of the second RF signal. The application of the first RF signal is synchronized to application of the second RF signal. The first RF signal may be amplitude modulated in synchronization with the second RF signal, and the amplitude modulation can include blanking of the first RF signal. A frequency offset may be applied to the first RF signal in synchronization with the second RF signal. A variable actuator associated with the first RF power source may be controlled in accordance with the second RF signal.

Abstract: A radio frequency (RF) generator system includes first and second RF power sources, each RF power source applying a respective RF signal and second RF signal to a load. The first RF signal is applied in accordance with the application of the second RF signal. The application of the first RF signal is synchronized to application of the second RF signal. The first RF signal may be amplitude modulated in synchronization with the second RF signal, and the amplitude modulation can include blanking of the first RF signal. A frequency offset may be applied to the first RF signal in synchronization with the second RF signal. A variable actuator associated with the first RF power source may be controlled in accordance with the second RF signal.

Abstract: A method for optimizing delivery of power to a plasma chamber is described. The method includes dividing each cycle of a low frequency (LF) radio frequency generator (RFG) into multiple time intervals. During each of the time intervals, a frequency offset of a high frequency (HF) RFG is generated for which the delivery of power is maximized The frequency offsets provide a substantially inverse relationship compared to a voltage signal of the LF RFG for each cycle of the voltage signal. The frequency offsets for the time intervals are multiples of the low frequency. The substantially inverse relationship facilitates an increase in the delivery of power to the electrode. A total range of the frequency offsets from a reference HF frequency over the LF RF cycle depends on a power ratio of power that is supplied by the LF RFG and power that is supplied by the HF RFG.