A film forming apparatus includes a vacuum-evacuable processing chamber, a lower electrode for mounting thereon a target substrate, an upper electrode disposed to face the lower electrode, a gas supply unit, a voltage application unit and a switching unit. The gas supply unit supplies a film forming source gas to be formed into plasma to a processing space between the upper and the lower electrode. The voltage application unit applies to the upper electrode a voltage outputted from at least one of a high frequency power supply and a DC power supply included therein. The switching unit selectively switches the voltage to be applied to the upper electrode among a high frequency voltage outputted from the high frequency power supply, a DC voltage outputted from the DC power supply, and a superimposed voltage in which the DC voltage is superimposed with the high frequency voltage.

A radio frequency (RF) power generation system includes a RF power source that generates a RF output signal delivered to a load. A RF power controller is configured to generate a control signal to vary the RF output signal. The controller adjusts a parameter associated with the RF output signal, and the parameter is controlled in accordance with a trigger signal. The parameter is adjusted in accordance with a cost function, and the cost function is determined by intruding a perturbation into an actuator that affects the cost function. The actuator may control an external RF output signal, and the trigger signal may vary in accordance with the external RF output signal.

A reactor system comprises a process chamber, a gas inlet, and a dispenser. The dispenser is coupled to the gas inlet. The dispenser controls a gas flow from a vial to the gas inlet. The vial includes a coating material that, when released inside the process chamber under operating conditions of the reaction system, coats an inner wall of the process chamber.

A power supply system includes a RF generator, a matching network, and a control module. The matching network includes at least one mechanically variable impedance element and at least one electrically variable impedance element. The control module is coupled to the matching network and configured to generate one or more signals to adjust at least one of an impedance of the mechanically variable impedance element or an impedance of the electrically variable impedance element to vary an impedance match between the generator and a load. In other examples, a hybrid variable impedance module includes at least one mechanically variable impedance element, at least one electrically variable impedance element, and a control module. The control module is configured to generate one or more signals to adjust at least one of an impedance of the mechanically variable impedance element or an impedance of the electrically variable impedance element.

A plasma processing apparatus includes: a first electrode on which a substrate is placed; a plasma generation source that generates plasma; a bias power supply that supplies bias power to the first electrode; a source power supply that supplies source power to the plasma generation source; and a controller. The controller performs a control such that a first state and a second state of the source power are alternately applied in synchronization with a high frequency cycle of the bias power, or a phase within one cycle of a reference electrical state indicating any one of a voltage, a current and an electromagnetic field measured in a power feed system of the bias power, and performs a control to turn OFF the source power at least at a negative side peak of the phase within one cycle of the reference electrical state.

An impedance matching circuit includes a radiofrequency terminal and a series circuit connected to the radiofrequency terminal, wherein the series circuit comprises at least one reactance and at least one switching element having a drive input. A drive circuit is connected to the drive input and a coupler is connected to the drive circuit so as to an enable signal input. The impedance matching circuit enables short switching times and low losses in the at least one switching element.

A multi-signal radio frequency (RF) source includes an RF source; and a switch including an input in communication with an output of the RF source, a first output and a second output. The switch is configured to selectively connect the input to one of the first output and the second output. An RF generator in communication with the first output of the multi-signal RF source is configured to generate plasma in a processing chamber. A remote plasma generator in communication with the second output of the multi-signal RF source is configured to supply remote plasma to the processing chamber.

Systems and methods for using a transformer to achieve uniformity in processing a substrate are described. One of the systems includes a primary winding having a first end and a second end. The first end is coupled to an output of an impedance matching circuit and the second end is coupled to a capacitor. The system further includes a secondary winding associated with the primary winding and coupled to a first end and a second end of a transformer coupled plasma (TCP) coil of a plasma chamber. The primary winding receives a modified radio frequency (RF) signal from the impedance matching circuit to generate a magnetic flux to induce a voltage in the secondary winding. An RF signal generated by the voltage is transferred from the secondary winding to the TCP coil.

A RF generator includes a RF power source and a RF control module coupled to the RF power source. The RF control module is configured to generate at least one control signal to vary a respective at least one of an RF output signal from the RF power source or an impedance between the RF power source and a load. The RF output signal includes a RF signal modulated by a pulse signal, and the RF control module is further configured to adjust the at least one control signal to vary at least one of an amplitude or a frequency of the RF output signal or the impedance between the RF power source and the load to control a shape of the pulse signal. The at least one of the amplitude, the frequency, or the impedance is adjusted in accordance with respective feedforward adjustments that vary in accordance with a respective sensed pulse parameter detected between a matching network and the load.

Various embodiments are directed to a switch circuit comprising: two terminal nodes, comprising an upper node and a lower node; a plurality of switch modules, connected in series between the upper node and the lower node, wherein each of the switch modules comprises a switch, a rectifier, and a capacitor; a connecting circuit, coupled to the switch modules; and a power converter, coupled to the connecting circuit and to a power sink. The switch circuit is configured to limit a voltage or a component of a voltage in the switch circuit, and to recover power from the limiting of the voltage, wherein recovering the power comprises diverting power from the switch modules via the connecting circuit to the power converter, and the power converter outputting the power to the power sink.