An RF plasma generator configured to ignite and maintain a plasma from one or more processing gases is disclosed. A switch mode power supply is configured to convert a DC voltage from a DC power source to an RF voltage. A resonance circuit is configured to deliver an amount of power to an ignited plasma from the switch mode power supply. A plasma controller is configured to operate the power supply to apply an RF voltage corresponding to the amount of power to the one or more processing gases through the resonance circuit. The RF voltage increases in amplitude and decreases in frequency until the one or more processing gasses are ignited into a plasma. Responsive to detecting ignition of the plasma, the plasma controller is further configured to continuously adjust the frequency of the switch mode power supply to deliver the amount of power to the ignited plasma. The amount of power is a substantially constant amount of power.

In one embodiment, a method, a method of manufacturing a semiconductor is disclosed. A monitored semiconductor manufacturing system (monitored system) is operated over a period of time, the monitored system comprising an impedance matching network coupled between a radio frequency (RF) source and a plasma chamber. First values for a parameter of the monitored system are received, the first values comprising different values for the parameter over the time period of operation of the monitored system, and a learning model is trained using the first values for the parameter. A substrate is then placed in a plasma chamber of a controlled semiconductor manufacturing system (controlled system). A characteristic of the controlled system is determined using a current value of the parameter and the trained learning model. An action is then taken upon the controlled system to address the determined characteristic.

In accordance with an embodiment, a measurement system includes a sensor circuit configured to provide a voltage sense signal proportional to an electric field sensed by the RF sensor and a current sense signal proportional to a magnetic field sensed by the RF sensor; an analysis circuit comprising a frequency selective demodulator circuit configured to: demodulate the voltage sense signal into a first set of analog demodulated signals according to a set of demodulation frequencies, demodulate the current sense signal into a second set of analog demodulated signals according to the set of demodulation frequencies, and determine a phase shift between the voltage sense signal and the current sense signal for at least one frequency of the set of demodulation frequencies; and analog-to-digital converters configured to receive the first and second sets of analog demodulated signals.

Processing methods and apparatus for increasing a reaction chamber batch size. Such a method of processing deposition substrates (e.g., wafers), involves conducting a deposition on a first portion of a batch of deposition wafers in a reaction chamber, conducting an interval conditioning reaction chamber purge to remove defects generated by the wafer processing from the reaction chamber; and following the interval conditioning mid-batch reaction chamber purge, conducting the deposition on another portion of the batch of wafers in the reaction chamber. The interval conditioning reaction chamber purge is conducted prior to exceeding a baseline for acceptable defect (e.g., particle) generation in the chamber and is performed while no wafers are positioned in the reaction chamber.

A magnetron structure is described for use in a sputtering apparatus. The magnetron structure comprises a magnetron and a controller rigidly connected to the magnetron. The controller is adapted for at least partly controlling a condition and/or a functioning of the sputtering unit.

A substrate processing tool capable of detecting a gap and/or shifting of a substrate clamped to a clamping surface in a processing chamber based on observed behavior of RF power delivered to the processing chamber during processing. The behavior of the RF power is observed by comparing a voltage-current phase angle difference and/or impedance magnitude change between a real RF power component and a reactive RF power component of the RF power delivered to the processing chamber.

Systems and methods for identifying a single failure in a heater array and compensating for the failure are described. The methods include identifying two X buses and two Y buses of the heater array having a location of the failure. A confirmation of the single failure within the heater array is performed after identifying the two X and two Y buses. Once the single failure is confirmed, the location of the failure is identified. The methods include compensating for the single failure by adjusting a duty cycle of a heater at the location of the failure, adjusting additional duty cycles of heaters along the same X bus as the failed heater and the same Y bus as the failed heater, and maintaining remaining duty cycles of power provided to remaining heaters of the heater array.

A plasma control apparatus includes a power source unit, a resonance producing unit, and a voltmeter. The resonance producing unit includes an LC circuit formed by a coil L1 and a capacitor C1 connected to each other, and a sensor S2 configured to detect a phase difference between current flowing in and voltage applied to the LC circuit, and the capacitor C1 of the LC circuit has a capacitance larger than an expected capacitance of the plasma P. The power source unit 1 configured to control the magnitude of radio-frequency power to be supplied in such a manner as to bring the voltage measured with the voltmeter 5 close to a set voltage as a target, and controls the frequency of the radio-frequency power to be supplied in such a manner as to minimize the phase difference detected with the sensor S2.

Systems and methods for achieving a pre-determined factor associated with the edge region within the plasma chamber is described. One of the methods includes providing an RF signal to a main electrode within the plasma chamber. The RF signal is generated based on a frequency of operation of a first RF generator. The method further includes providing another RF signal to an edge electrode within the plasma chamber. The other RF signal is generated based on the frequency of operation of the first RF generator. The method includes receiving a first measurement of a variable, receiving a second measurement of the variable, and modifying a phase of the other RF signal based on the first measurement and the second measurement. The method includes changing a magnitude of a variable associated with a second RF generator to achieve the pre-determined factor.

Methods and apparatus for processing a substrate are provided herein. For example, apparatus can include a system for processing a substrate, comprising: a remote plasma source including a supply terminal configured to connect to a power source and an output configured to deliver RF power to a plasma block of the remote plasma source for creating a plasma; and a controller connected to the supply terminal of the remote plasma source and configured to determine, based on a predictive model of the remote plasma source, whether a power at the supply terminal is equal to a predetermined threshold during processing of a substrate, wherein the predictive model includes a correlation of remote plasma performance with delivered RF power at the output, and to control the processing of the substrate based on a determination of the predetermined threshold being met to control processing of the substrate.