One or more embodiments described herein generally relate to methods for chucking and de-chucking a substrate to/from an electrostatic chuck used in a semiconductor processing system. Generally, in embodiments described herein, the method includes: (1) applying a first voltage from a direct current (DC) power source to an electrode disposed within a pedestal; (2) introducing process gases into a process chamber; (3) applying power from a radio frequency (RF) power source to a showerhead; (4) performing a process on the substrate; (5) stopping application of the RF power; (6) removing the process gases from the process chamber; and (7) stopping applying the DC power.

Embodiments described herein relate to apparatus and methods for performing electron beam reactive plasma etching. In one embodiment, an apparatus for performing EBRPE processes includes an electrode formed from a material having a high secondary electron emission coefficient. The electrode has an electron emitting surface disposed at a nonparallel angle relative to a major axis of a substrate assembly. The EBRPE apparatus may further comprise a capacitive or inductive coupled plasma generator. In another embodiment, methods for etching a substrate include generating a plasma and bombarding an electrode with ions from the plasma to cause the electrode to emit electrons. The electrons are accelerated toward a substrate to induce directional etching of the substrate. During the EBPRE process, the substrate or electrode is actuated through a process volume during the etching.

In an embodiment, a plasma source includes a first electrode, configured for transfer of one or more plasma source gases through first perforations therein; an insulator, disposed in contact with the first electrode about a periphery of the first electrode; and a second electrode, disposed with a periphery of the second electrode against the insulator such that the first and second electrodes and the insulator define a plasma generation cavity. The second electrode is configured for movement of plasma products from the plasma generation cavity therethrough toward a process chamber. A power supply provides electrical power across the first and second electrodes to ignite a plasma with the one or more plasma source gases in the plasma generation cavity to produce the plasma products. One of the first electrode, the second electrode and the insulator includes a port that provides an optical signal from the plasma.

Embodiments described herein relate to apparatus and methods for performing electron beam etching process. In one embodiment, a method of etching a substrate includes delivering a process gas to a process volume of a process chamber, applying a RF power to an electrode formed from a high secondary electron emission coefficient material disposed in the process volume, generating a plasma comprising ions in the process volume, bombarding the electrode with the ions to cause the electrode to emit electrons and form an electron beam, applying a negative DC power to the electrode, accelerating electrons emitted from the bombarded electrode toward a substrate disposed in the process chamber, and etching the substrate with the accelerated ions.

An ARC evaporator comprising: a cathode assembly comprising a cooling plate (11), a target (1) as cathode element, an electrode arranged for enabling that an arc between the electrode and the front surface (1A) of the target (1) can be established a magnetic guidance system placed in front of the back surface (1 B) of the target (i) comprising means for generating one or more magnetic whereas: the borders of the cathode assembly comprise a surrounding shield (15) made of ferromagnetic material, wherein the surrounding shield (15) has a total height (H) in the transversal direction, said total height (H) including a component (C) for causing a shielding effect of magnetic field lines extending in any longitudinal directions, establishing in this manner the borders of the cathode assembly as limit of the extension of the magnetic field lines in any longitudinal direction.

Methods for controlling glow discharge in a plasma chamber are disclosed. One method includes connecting a radio frequency (RF) generator to a top electrode of a chamber, the chamber having chamber walls coupled to ground and connecting the RF generator to a bottom electrode of the chamber. Identifying a process operation of deposition to be performed in the chamber and setting an RF signal from the RF generator to be supplied to the top electrode at a first phase. And, setting the RF signal from the RF generator to be supplied to the bottom electrode at a second phase. The first phase and the second phase being adjustable to a phase difference to cause the plasma glow discharge to be controllably positioned within the chamber based on the phase difference.

A charged particle multi-beam device includes a charged particle source, a collimator lens, a multi-light-source forming unit, and a reduction projection optical system. The multi-light-source forming unit has first to third porous electrodes disposed side by side in an optical axis direction. A plurality of holes for causing the multi-beams to pass is formed in each of the first to third porous electrodes. The first porous electrode and the third porous electrode have the same potential and the second porous electrode has potential different from the potential of the first porous electrode and the third porous electrode. A diameter of the holes on the second porous electrode is formed larger further away from an optical axis such that a surface on which the multi-light sources are located is formed in a shape convex to the charged particle source side.

Plasma source assemblies comprising an RF hot electrode having a body and at least one return electrode spaced from the RF hot electrode to provide a gap in which a plasma can be formed. An RF feed is connected to the RF hot electrode at a distance from the inner peripheral end of the RF hot electrode that is less than or equal to about 25% of the length of the RF hot electrode. The RF hot electrode can include a leg and optional triangular portion near the leg that extends at an angle to the body of the RF hot electrode. A cladding material on one or more of the RF hot electrode and the return electrode can be variably spaced or have variable properties along the length of the plasma gap.

An object of the present invention is to reduce non-uniformity of etching in a plane of a wafer. An electrostatic chuck device includes: an electrostatic chuck part having a sample mounting surface on which a sample is mounted and having a first electrode for electrostatic attraction; a cooling base part placed on a side opposite to the sample mounting surface with respect to the electrostatic chuck part to cool the electrostatic chuck part; and an adhesive layer that bonds the electrostatic chuck part and the cooling base part together, in which the cooling base part has a function of a second electrode that is an RF electrode, a third electrode for RF electrode or LC adjustment is provided between the electrostatic chuck part and the cooling base part, and the third electrode is bonded to the electrostatic chuck part and the cooling base part and insulated from the cooling base part.

A plasma processing method is performed by a plasma processing apparatus that includes a process chamber, a conductive first component that is disposed in the process chamber and at least a surface of which is covered with a conductive silicon material, and a second component that is disposed in the process chamber and is at a ground potential or a floating potential with respect to an electric potential of plasma. The method includes forming an oxide layer on the surface of the first component by converting an oxygen-containing gas into plasm, and treating a surface of the second component by converting a halogen-containing gas into plasm.