Process kits, processing chambers, and methods for processing a substrate are provided. The process kit includes an edge ring, a sliding ring, an adjustable tuning ring, and an actuating mechanism. The edge ring has a first ring component interfaced with a second ring component that is movable relative to the first ring component forming a gap therebetween. The sliding ring is positioned beneath the second ring component of the edge ring. The adjustable tuning ring is positioned beneath the sliding ring. The actuating mechanism is interfaced with the lower surface of the adjustable tuning ring and configured to actuate the adjustable tuning ring such that the gap between the first and second ring components is varied. In one or more examples, the sliding ring includes a matrix and a coating, the matrix contains an electrically conductive material and the coating contains an electrically insulting material.

A system for fabricating a semiconductor device may include a chamber, an electrostatic chuck used to load a substrate, a power source supplying an RF power to the electrostatic chuck, an impedance matcher between the power source and the electrostatic chuck, and a power transmission unit connecting the electrostatic chuck to the impedance matcher. The power transmission unit may include a power rod, which is connected to the electrostatic chuck and has a first outer diameter, and a coaxial cable. The coaxial cable may include an inner wire, an outer wire, and a dielectric material between the outer and inner wires. The inner wire connects the power rod to the impedance matcher and has a second outer diameter less than the first outer diameter. The outer wire is connected to the chamber and is provided to enclose the inner wire and has a first inner diameter less than the first outer diameter and greater than the second outer diameter. A ratio of the first inner diameter to the second outer diameter is greater than a dielectric constant of the dielectric material and less than three times the dielectric constant of the dielectric material.

Methods and systems for dry etching are disclosed. The methods and systems use a showerhead with a perforated plate. The perforated plate includes a primary solid zone having no holes; a first annular zone comprising a first plurality of holes with a first total hole area; a secondary solid zone having no holes; a second annular zone comprising a second plurality of holes with a second total hole area; a third annular zone comprising a third plurality of holes with a third total hole area; and a fourth annular zone comprising a fourth plurality of holes with a fourth total hole area. The third total hole area is greater than the first total hole area and less than the second total hole area, and the fourth total hole area is greater than the second total hole area. Dry etched wafers using these systems have improved edge uniformity and improved yield.

A plasma processing apparatus, including a processing; a first radio frequency power source; a sample stage on which the sample is placed; a second radio frequency power; and a control device configured to control, when the second radio frequency power source is controlled based on a change in a plasma impedance, which is generated when a first gas that is a gas for a first step is switched to a second gas that is a gas for a second step, such that the second radio frequency power is changed from a value of the second radio frequency power in the first step to a value of the second radio frequency power in the second step, and a supply time of the first gas such that a supply time of the second radio frequency power in the first step is substantially equal to a time of the first step.

A plasma processing apparatus includes: a processing chamber in which a sample is subjected to plasma treatment; a radio frequency power supply configured to supply radio frequency power that generates plasma; a sample stage on which the sample is placed; and an ultraviolet light source configured to apply an ultraviolet ray. The apparatus further includes a controller configured to control the ultraviolet light source such that before the radio frequency power is supplied into the processing chamber, a pulse-modulated ultraviolet ray is applied into the processing chamber.

Embodiments for the present application include methods and apparatus for operating a plasma enhanced substrate processing system using dual level pulsed radio frequency (RF) power. More specifically, embodiments of the present disclosure allow for frequency and power tuning in a process chamber using dual level pulsed power by using a tuning controller coupled to a matching network and/or a RF power generator. In one embodiment, a tuning system includes a tuning controller disposed in a tuning system, the tuning controller configured to tune dual level RF pulsing data from a RF power generator, wherein the tuning system is connectable to a plasma processing chamber, and a memory connecting to the tuning controller, wherein the tuning controller is configured to couple to a RF power generator and a matching network disposed in the plasma processing chamber.

A device and method of spreading plasma which allows for plasma etching over a larger range of process chamber pressures. A plasma source, such as a linear inductive plasma source, may be choked to alter back pressure within the plasma source. The plasma may then be spread around a deflecting disc which spreads the plasma under a dome which then allows for very even plasma etch rates across the surface of a substrate. The apparatus may include a linear inductive plasma source above a plasma spreading portion which spreads plasma across a horizontally configured wafer or other substrate. The substrate support may include heating elements adapted to enhance the etching.

There is provided a method for driving a member provided in a processing chamber. The method includes irradiating to the member measurement light having a wavelength that penetrates the member, detecting intensity distribution of reflected light based on reflected light from an upper surface of the member and reflected light from a bottom surface of the member, calculating an optical path difference by applying Fourier transform to a spectrum indicating the intensity distribution, and determining a driving amount of the member based on the optical path difference. The method further includes driving the member based on the determined driving amount.

Based on the fact that a film thickness of a film formed in a film formation processing of repeatedly performing a first sequence varies according to a temperature of the surface on which the film is to be formed, the film formation processing is performed after the temperature of each region of the surface of the wafer is adjusted to reduce a deviation of a trench on the surface of the wafer, so that the film is very precisely formed on the inner surface of the trench while reducing the deviation of the trench on the surface of the wafer. When the trench width is narrower than a reference width, an etching processing of repeatedly performing a second sequence is performed in order to expand the trench width, so that the surface of the film provided in the inner surface of the trench is isotropically and uniformly etched.

Process kits, processing chambers, and methods for processing a substrate are provided. The process kit includes an edge ring, a sliding ring, an adjustable tuning ring, and an actuating mechanism. The edge ring has a first ring component interfaced with a second ring component that is movable relative to the first ring component forming a gap therebetween. The sliding ring is positioned beneath the edge ring. The adjustable tuning ring is positioned beneath the sliding ring. The actuating mechanism is interfaced with the lower surface of the adjustable tuning ring and configured to actuate the adjustable tuning ring such that the gap between the first and second ring components is varied. In one or more examples, the sliding ring includes a matrix and a coating, the matrix contains an electrically conductive material and the coating contains an electrically insulting material.