A substrate support including a body, a heating element, a first radio frequency filter, and a second radio frequency filter. The body is configured to support a substrate. The heating element is at least partially implemented in a first portion of the body. The first radio frequency filter is connected to an input of the heating element and at least partially implemented in a second portion of the body and connected to the heating element by a first via. The second radio frequency filter is connected to an output of the heating element and at least partially implemented in the second portion or a third portion of the body.

The inventive concept provides a substrate treating apparatus. The substrate treating apparatus includes a chamber providing a treating space; a substrate support unit provided in the treating space; a window provided at a top of the chamber; and an optical module provided over the window and configured to transmit a laser beam to a substrate through the window, and wherein the optical module includes: a homogenizing optics configured to homogenize the laser beam to a uniform beam profile; and an imaging optics configured to control the size of the laser beam.

Embodiments provided herein generally include apparatus, plasma processing systems and methods for boosting a voltage of an electrode in a processing chamber. An example plasma processing system includes a processing chamber, a plurality of switches, an electrode disposed in the processing chamber, a voltage source, and a capacitive element. The voltage source is selectively coupled to the electrode via one of the plurality of switches. The capacitive element is selectively coupled to the electrode via one of the plurality of switches. The capacitive element and the voltage source are coupled to the electrode in parallel. The plurality of switches are configured to couple the capacitive element and the voltage source to the electrode during a first phase, couple the capacitive element and the electrode to a ground node during a second phase, and couple the capacitive element to the electrode during a third phase.

A substrate support that supports a substrate, includes a substrate attraction part having an attraction electrode for holding the substrate, an RF electrode part to which RF power is supplied, and a substrate temperature adjuster having a heater electrode for adjusting a temperature of the substrate. The substrate attraction part and the substrate temperature adjuster are stacked with the RF electrode part interposed therebetween.

A physical vapor deposition processing chamber is described. The processing chamber includes a target backing plate in a top portion of the processing chamber, a substrate support in a bottom portion of the processing chamber, a deposition ring positioned at an outer periphery of the substrate support and a shield. The substrate support has a support surface spaced a distance from the target backing plate to form a process cavity. The shield forms an outer bound of the process cavity. In-chamber cleaning methods are also described. In an embodiment, the method includes closing a bottom gas flow path of a processing chamber to a process cavity, flowing an inert gas from the bottom gas flow path, flowing a reactant into the process cavity through an opening in the shield, and evacuating the reaction gas from the process cavity.

An arc detector for a RF power supply system, where the RF power supply incudes a first RF power supply and a second RF power supply. A signal applied to a non-linear load varies in accordance with an output from one of the first RF power supply or the second RF power supply. The signal has a frequency. During an arc or arc condition in the non-linear load, the frequency of the signal changes, and if the frequency is outside of a selected range, an arc or arc condition is indicated. The frequency can be determined by digitizing the signal into a series of pulses and measuring a time or period between pulses.

Methods and apparatus for controlling plasma in a process chamber leverage an RF termination filter which provides an RF path to ground. In some embodiments, an apparatus may include a DC filter configured to be electrically connected between a DC power supply and electrodes embedded in an electrostatic chuck where the DC filter is configured to block DC current from the DC power supply from flowing through the DC filter and an RF termination filter configured to be electrically connected between the DC filter and an RF ground of the process chamber where the RF termination filter is configured to adjust an impedance of the electrodes relative to the RF ground.

A plasma processing apparatus disclosed herein includes a substrate support provided in a chamber; a radio-frequency power supply configured to supply radio-frequency power to generate plasma in the chamber; and a bias power supply configured to supply electric bias energy to an electrode to draw ions into a substrate on the substrate support. The electric bias energy has a cycle having a time length reciprocal to a bias frequency. The radio-frequency power supply is further configured to adjust an output power level of the radio-frequency power in a plurality of phase periods in the cycle such that an evaluation value is less than or equal to a first value, the evaluation value being a power level of reflected waves of the radio-frequency power or a value of a ratio of the power level to the output power level.

An etching method includes: preparing a substrate including a first region containing silicon and nitrogen, and a second region containing silicon and oxygen; and etching the second region while firming a tungsten-containing protective layer on the first region, by exposing the first and second regions to plasma generated from a processing gas containing carbon, fluorine, and tungsten.

A power supply control system includes a power generator for providing a signal to a load. The power generator includes a power controller controlling a power amplifier. The power generator includes an adaptive controller for varying the output signal controlling the power amplifier. The adaptive controller compares an error between a measured output and a predicted output to determine adaptive values applied to the power controller. The power generator also includes a sensor that generates an output signal that is digitized and processed. The sensor signal is mixed with a constant K. The constant K is varied to vary the processing of the sensor output signal. The value K may be commutated based on the phase, frequency, or both phase and frequency, and the bandwidth of K is determined by coupled power in the sensor output signal.