A substrate support is provided in a chamber of a plasma processing apparatus according to an exemplary embodiment. The substrate support has a lower electrode and an electrostatic chuck. A matching circuit is connected between a power source and the lower electrode. A first electrical path connects the matching circuit and the lower electrode to each other. A second electrical path different from the lower electrode is provided to supply electric power from the matching circuit to a focus ring. A sheath adjuster is configured to adjust a position of an upper end of a sheath on/above the focus ring. A variable impedance circuit is provided on the first or second electrical path.

A mounting table includes a base member, having a rear surface and a front surface facing the rear surface, in which a coolant path is formed, a groove portion having a bottom surface within the base member being annularly formed on the front surface, the base member being divided into a cylindrical inner base member portion positioned at an inner side of the groove portion and an annular outer base member portion positioned at an outer side of the groove portion by the groove portion; an annular focus ring supported by the outer base member portion, the annular focus ring having, at an inner side surface thereof, a protrusion that is protruded radially and inwardly to cover the groove portion; a first heat transfer member provided between the mounting surface and the coolant path; and the second heat transfer member provided between the focus ring and the coolant path.

A plasma processing apparatus includes a chamber providing a space for processing a substrate, a substrate stage configured to support the substrate within the chamber and including a lower electrode, an upper electrode facing the lower electrode, a focus ring in or on an upper peripheral region of the substrate stage to surround the substrate, and a plasma adjustment assembly in at least one of a first position between the upper electrode and the lower electrode and a second position between the focus ring and the lower electrode, the plasma adjustment assembly including a photoreactive material layer and a plurality of light sources configured to irradiate light onto a local region of the photoreactive material layer. A capacitance of the local region is changed as the light is irradiated to the local region.

Provided is a generator including a power amplifier, at least one sampler, an RF output, a signal generator, a controller including a digital control portion and an analogue control portion, an analogue feedback path between the at least one sampler and the controller enabling an analogue signal representation of a signal to be provided to the controller, and a digital feedback path between the at least one sampler and the controller enabling a digital signal representation of the signal to be provided to the controller. The controller is configured to adjust the RF signal at the RF output from a first state into a second state based on the analogue signal representation and/or the digital signal representation.

A plasma processing apparatus includes a mounting table, an acquisition unit, a calculation unit, and an elevation control unit. The mounting table mounts thereon a target object as a plasma processing target. The elevation mechanism vertically moves a focus ring surrounding the target object. The acquisition unit acquires state information indicating a measured state of the target object. The calculation unit calculates a height of the focus ring at which positional relation between an upper surface of the target object and an upper surface of the focus ring satisfies a predetermined distance based on the state of the target object that is indicated by the state information acquired by the acquisition unit. The elevation control unit controls the elevation mechanism to vertically move the focus ring to the height calculated by the calculation unit.

There is provided a plasma processing apparatus comprising: a processing container; a lower electrode provided inside the processing container; an upper electrode disposed to face the lower electrode; a gas supply configured to supply a processing gas between the upper electrode and the lower electrode; a high frequency power source configured to generate plasma of the processing gas by applying a high frequency voltage to the upper electrode; and a voltage waveform shaping part provided between the high frequency power source and the upper electrode and configured to shape a voltage waveform of a high frequency voltage output from the high frequency power source by converting a positive voltage component into a negative voltage component.

In some implementations, a method for performing a plasma process in a chamber is provided, including: supplying a process gas to the chamber; applying pulsed RF power to the process gas in the chamber, the pulsed RF power being provided at a predefined frequency, wherein the applying of the pulsed RF power to the process gas generates a plasma in the chamber; during the applying of the RF power, applying a pulsed DC current to a magnetic coil that is disposed over the chamber, wherein the pulsed DC current is provided at the predefined frequency.

There is provided a filter device. In the filter device, a plurality of coils are arranged coaxially. Each of a plurality of wirings is electrically connected to one end of each of the coils. Each of a plurality of capacitors is connected between the other end of each of the coils and the ground. A housing is electrically grounded and configured to accommodate therein the coils. Further, each of the wirings at least partially extends into the housing and has a length that is adjustable in the housing.

Exemplary semiconductor substrate supports may include a pedestal shaft. The semiconductor substrate supports may include a platen. The platen may define a fluid channel across a first surface of the platen. The semiconductor substrate supports may include a platen insulator positioned between the platen and the pedestal shaft. The semiconductor substrate supports may include a conductive puck coupled with the first surface of the platen and configured to contact a substrate supported on the semiconductor substrate support. The semiconductor substrate supports may include a conductive shield extending along a backside of the platen insulator and coupled between a portion of the platen insulator and the pedestal shaft.

An etching apparatus includes: a chamber; a substrate support disposed in the chamber; one or more heaters disposed in the substrate support; a gas supply; a plasma generator; a controller configured to perform an etching process comprising a plurality of cycles; and a heater controller. Each cycle includes: controlling the gas supply to supply a precursor into the chamber, thereby forming a precursor layer on a substrate supported by the substrate support, the substrate including a film and a mask; and controlling the gas supply and the plasma generator to supply a process gas into the chamber and generate a plasma from the process gas in the chamber, thereby etching the film through the mask.