Provided is a filter device including a plurality of coils, a plural of capacitors, and a frame. The coils constitute a plurality of coil groups. Each coil group includes two or more coils. The two or more coils in each coil group are provided such that respective windings of the two or more coils extend spirally about a central axis and respective turns of the two or more coils are sequentially and repeatedly arranged in an axial direction in which the central axis extends. The coil groups are provided coaxially with the central axis. A pitch between the respective turns of the two or more coils of any one coil group among the coil groups is larger than a pitch between the respective turns of the two or more coils of the coil group provided inside the one coil group among the coil groups.

Provided is a filter device includes: a first coil group including a plurality of coils arranged along a central axis and spirally wound with a first inner diameter; and a second coil group including a plurality of coils arranged along the central axis and spirally wound with a second inner diameter larger than the first inner diameter. A pitch between respective turns of the plurality of coils of the second coil group is larger than a pitch between respective turns of the plurality of coils of the first coil group.

Systems and methods for plasma processing are disclosed. An exemplary system may include a plasma processing chamber including a source to produce a plasma in the processing chamber and at least two bias electrodes arranged within the plasma processing chamber to control plasma sheaths proximate to the bias electrodes. A chuck is disposed to support a substrate, and a source generator is coupled to the plasma electrode. At least one bias supply is coupled to the at least two bias electrodes, and a controller is included to control the at least one bias supply to control the plasma sheath(s) proximate to the bias electrodes.

A plasma processing apparatus comprising: a chamber; a substrate support disposed in the chamber and including a lower electrode, a substrate supporting surface for supporting a substrate, and an edge ring disposed to surround the substrate placed on the substrate supporting surface; an upper electrode disposed above the lower electrode; a power supply portion configured to supply two or more powers having different frequencies, the power supply portion including a source power supply configured to supply a source power for generating plasma from a gas in the chamber to the upper electrode or the lower electrode, and at least one bias power supply configured to supply one bias power or two or more bias powers having different frequencies to the lower electrode; at least one variable passive component electrically connected to the edge ring; and at least one bypass circuit that electrically connects the power supply portion and the edge ring and is configured to supply a part of at least one power selected from the group consisting of the source power and at least one bias power to the edge ring.

A plasma etching method and a semiconductor device fabrication method, the plasma etching method including providing a source power having a first single pulse to an electrostatic chuck in order to generate a plasma on a substrate; providing a first bias power having a burst pulse different from the first single pulse to concentrate the plasma on the substrate; and providing a second bias power having a second single pulse the same as the first single pulse to accelerate the plasma toward the substrate.

A plasma processing method is disclosed that includes (a) placing a substrate on an electrostatic chuck at a first temperature, the electrostatic chuck being disposed in a plasma processing chamber; (b) electrostatically attracting the substrate to the electrostatic chuck; (c) starting supply of a heat transfer gas between the substrate and the electrostatic chuck; (d) detecting a flow rate of the heat transfer gas or a pressure between the substrate and the electrostatic chuck; (e) determining whether the flow rate or the pressure exceeds a predetermined threshold value; (f) raising the temperature of the electrostatic chuck until the temperature of the electrostatic chuck becomes a second temperature, the second temperature being higher than the first temperature; and (g) generating plasma in the plasma processing chamber.

Embodiments herein provide plasma processing chambers and methods configured for fine-tuning and control over a plasma sheath formed during the plasma-assisted processing of a semiconductor substrate. Embodiments include a sheath tuning scheme, including plasma processing chambers and methods, which can be used to tailor one or more characteristics of a plasma sheath formed between a bulk plasma and a substrate surface. Generally, the sheath tuning scheme provides differently configured pulsed voltage (PV) waveforms to a plurality of bias electrodes embedded beneath the surface of a substrate support in an arrangement where each of the electrodes can be used to differentially bias a surface region of a substrate positioned on the support. The sheath tuning scheme disclosed herein can thus be used to adjust and/or control the directionality, and energy and angular distributions of ions that bombard a substrate surface during a plasma-assisted etch process.

A plasma etching apparatus may include a first source electrode, a first bias electrode, and a second bias electrode configured to generate a plasma by supplying energy to a process gas injected into a chamber; and a controller. The controller may be configured to supply a first high-frequency RF power, a first low-frequency RF power, and a second low-frequency RF power to the chamber during a first period from a first time to a second time; ramp down and turn off the first high-frequency RF power to the chamber during a second period from the second time to a third time; and ramp down and turn off the first low-frequency RF power to the chamber during a third period from the second time to a fourth time different from the third time. The third period may be smaller than ½ of the first period and greater than the second period.

Methods for depositing a dielectric material using RF bias pulses along with remote plasma source deposition for manufacturing semiconductor devices, particularly for filling openings with high aspect ratios in semiconductor applications are provided. For example, a method of depositing a dielectric material includes providing a gas mixture into a processing chamber having a substrate disposed therein, forming a remote plasma in a remote plasma source and delivering the remote plasma to an interior processing region defined in the processing chamber, applying a RF bias power to the processing chamber in pulsed mode, and forming a dielectric material in an opening defined in a material layer disposed on the substrate in the presence of the gas mixture and the remote plasma.

A sample releasing method for releasing a sample subjected to plasma processing from a sample stage on which the sample is electrostatically attracted by applying DC voltage to an electrostatic chuck electrode, and the method includes: moving the sample subjected to the plasma processing upward above the sample stage; and after moving the sample, controlling the DC voltage such that an electric potential of the sample is to be smaller.