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.

Embodiments provided herein generally include apparatus, e.g., plasma processing systems, and methods for the plasma processing of a substrate in a processing chamber. Some embodiments are directed to a waveform generator. The waveform generator generally includes a first voltage stage having: a first voltage source; a first switch; and a second switch, where a first terminal of the first voltage source is coupled to a first terminal of the first switch, and where a second terminal of the first voltage source is coupled to a first terminal of the second switch. The waveform generator also includes a current stage coupled to a common node between second terminals of the first switch and the second switch, the current stage having a current source and a third switch coupled to the current source.

There is provided a technique capable of improving a uniformity of a substrate processing on a substrate surface. According to one aspect thereof, there is provided a substrate processing apparatus including: a substrate processing room; a plasma generation room; a gas supplier supplying a gas into the plasma generation room; a first coil surrounding the plasma generation room and to which an electric power is supplied; and a second coil surrounding the plasma generation room and to which an electric power is supplied. An axial direction of the second coil is equal to that of the first coil, a winding diameter of the second coil is different from that of the first coil, and a peak of a voltage distribution generated by supplying the electric power to the second coil does not overlap with a peak of a voltage distribution generated by the first coil.

Embodiments provided herein generally include apparatus, plasma processing systems and methods for generation of a waveform for plasma processing of a substrate in a processing chamber. Embodiments of the disclosure include an apparatus and method for generating a pulsed-voltage waveform that includes coupling a main voltage source to an electrode during a first phase of a process of generating a pulsed-voltage waveform, wherein the electrode is disposed within a processing chamber, coupling a ground node to the electrode during a second phase of the process of generating the pulsed-voltage waveform, coupling a first compensation voltage source to the electrode during a third phase of the process of generating the pulsed-voltage waveform, and coupling a second compensation voltage source to the electrode during a fourth phase of the process of generating the pulsed-voltage waveform.

In a disclosed inspection method, a substrate and an edge ring are placed on first and second regions, respectively. A first inspection circuit is connected to the substrate. The first inspection circuit has impedance. A second inspection circuit is connected to the edge ring. The second inspection circuit has impedance. A first electrical bias and a second electrical bias having a common bias frequency are applied to a first electrode in the first region and a second electrode in the second region, respectively. A voltage waveform of the substrate and a voltage waveform of the edge ring is acquired by using a waveform monitor.

Embodiments provided herein include an apparatus and methods for the plasma processing of a substrate in a processing chamber. In some embodiments, aspects of the apparatus and methods are directed to reducing defectivity in features formed on the surface of the substrate, improving plasma etch rate, and increasing selectivity of etching material to mask and/or etching material to stop layer. In some embodiments, the apparatus and methods enable processes that can be used to prevent or reduce the effect of trapped charges, disposed within features formed on a substrate, on the etch rate and defect formation. In some embodiments, the plasma processing methods include the synchronization of the delivery of pulsed-voltage (PV) waveforms, and alternately the delivery of a PV waveform and a radio frequency (RF) waveform, so as to allow for the independent control of generation of electrons that are provided, during one or more stages of a PV waveform cycle, to neutralize the trapped charges formed in the features formed on the substrate.

Embodiments provided herein generally include plasma processing systems configured to preferentially clean desired surfaces of a substrate support assembly by manipulating one or more characteristics of an in-situ plasma and related methods. In one embodiment, a plasma processing method includes generating a plasma in a processing region defined by a chamber lid and a substrate support assembly, exposing an edge ring and a substrate supporting surface to the plasma, and establishing a pulsed voltage (PV) waveform at the edge control electrode.

Embodiments provided herein generally include apparatus, e.g., plasma processing systems and methods for the plasma processing of a substrate in a processing chamber. In some embodiments, aspects of the apparatus and methods are directed to improving process uniformity across the surface of the substrate, reducing defectivity on the surface of the substrate, or both. In some embodiments, the apparatus and methods provide for improved control over the uniformity of a plasma formed over the edge of a substrate and/or the distribution of ion energies at the surface of the substrate. The improved control over the plasma uniformity may be used in combination with substrate handling methods, e.g., de-chucking methods, to reduce particulate-related defectivity on the surface of the substrate. In some embodiments, the improved control over the plasma uniformity is used to preferentially clean accumulated processing byproducts from portions of the edge ring during an in-situ plasma chamber cleaning process.

Plasma processing systems and methods are disclosed. The plasma processing system includes a high-frequency generator configured to deliver power to a plasma chamber and a low-frequency generator configured to deliver power to the plasma chamber. A filter is coupled between the plasma chamber and the high-frequency generator, and the filter suppresses mixing products of high frequencies produced by the high-frequency generator and low frequencies produced by the low-frequency generator.

A plasma processing apparatus includes a processing chamber in which a sample is subjected to plasma processing, a first radio frequency power supply that supplies radio frequency power for generating plasma, a sample stage on which the sample is mounted, and a second radio frequency power supply that supplies radio frequency power to the sample stage, the plasma processing apparatus further includes a DC power supply that applies a DC voltage, that is changed according to a periodically repeated waveform, to the sample stage, and the waveform of one cycle has a period in which amplitude changes by a predetermined amount or more during a predetermined time. Accordingly, charged particles on a wafer surface are removed, a trench shape with high verticality can be obtained, and damage to a film that is not to be etched inside a trench can be reduced.