A coil structure includes a coil set including a first coil and a second coil. The first coil and the second coil are wound to form an annular area. A first end of the first coil and a first end of the second coil are close to an inner ring of the annular area. A second end of the first coil and a second end of the second coil are close to an outer ring of the annular area. The first end of the first coil is electrically connected to the first end of the second coil. A first projection-of the first coil on a plane perpendicular to an axial direction of the coil structure and a second projection of the second coil on the plane are mirror-symmetrical to each other.

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.

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.

Disclosed is an apparatus for treating a substrate. The apparatus includes a chamber having a space therein in which the substrate is treated, a support unit that supports the substrate in the chamber, a gas supply unit that supplies gas into the chamber, and a plasma generation unit that excites the gas in the chamber into a plasma state. The support unit includes a support plate on which the substrate is placed, a high-frequency power supply that supplies high-frequency power to the support plate, and a high-frequency transmission line through which the high-frequency power is supplied from the high-frequency power supply to the support plate. Characteristic impedance of the high-frequency transmission line is variable.

An impedance match housing is described. The impedance match housing includes an impedance matching circuit having an input that is coupled to a radio frequency (RF) generator. The impedance matching circuit has an output that is coupled to a first RF strap. The impedance match housing includes a uniformity control circuit coupled in parallel to a portion of the first RF strap to modify uniformity in a processing rate of a substrate when the substrate is processed within a plasma chamber.

In a plasma processing apparatus, a mounting table have a first mounting surface on which a target object or a jig is mounted and a second mounting surface on which a ring member is mounted. The jig is used for measuring a thickness of the ring member disposed around the target object and having a facing portion facing an upper surface of the ring member. Elevating mechanisms lift or lower the ring member with respect to the second mounting surface. An acquisition unit acquires gap information indicating a gap dimension between the second mounting surface and the facing portion of the jig. A measurement unit measures a lifted distance of the ring member from the second mounting surface. A thickness calculation unit calculates the thickness of the ring member based on the gap dimension and the measured lifted distance of the ring member.

A processing chamber includes a grid and a first disk. The grid includes a plurality of holes arranged in the processing chamber. The grid partitions the processing chamber into a first chamber in which plasma is generated and a second chamber in which a pedestal is configured to support a substrate. The first disk is arranged in the second chamber. The first disk is movable between the grid and the substrate when supported on the pedestal.

The present invention relates to a method for etching lithium niobate, the method including a process of etching lithium niobate using a mask pattern as a physical dry etching method using Ar plasma produced in a chamber through Ar gas, wherein in the process of etching lithium niobate, a process pressure of the chamber is maintained at 1 mTorr to 20 mTorr, and a method for forming a lithium niobate pattern using the same.

An operation method of an etching apparatus includes transferring, from a load lock chamber to a process chamber, a substrate on which an etching target layer is formed, first etching the etching target layer on the substrate in a first etching time, transferring the substrate to a storage location in a state in a vacuum state, intermediate cleaning the process chamber in a first cleaning time, transferring the substrate from the storage location to the process chamber, second etching the etching target layer on the substrate in a second etching time, and returning the substrate to the load lock chamber. The etching target layer is formed in a predetermined etching pattern by the first etching and the second etching.

Devices and methods for controlling wafer uniformity in plasma-based process is disclosed. In one example, a device for plasma-based processes is disclosed. The device includes: a housing defining a process chamber and a gas distribution plate (GDP) arranged in the process chamber. The housing comprises: a gas inlet configured to receive a process gas, and a gas outlet configured to expel processed gas. The GDP is configured to distribute the process gas within the process chamber. The GDP has a plurality of holes evenly distributed thereon. The GDP comprises a first zone and a second zone. The first zone is closer to the gas outlet than the second zone. At least one hole in the first zone is closed.