An insulator for an ion implantation source may provide electrical insulation between high voltage components and relatively lower voltage components of the ion implantation source. To reduce the likelihood of and/or prevent a leakage path forming along the insulator, the insulator may include an internal cavity having a back and forth pattern. The back and forth pattern of the internal cavity increases the mean free path of gas molecules in the ion implantation source and increases the surface area of the insulator that is not directly or outwardly exposed to the gas molecules. This results in a continuous film or coating being more difficult and/or less likely to form along the insulator, which extends the working time of the ion implantation source.

An etching chamber 1 incorporates a focus ring 9 so as to surround a semiconductor wafer W provided on a lower electrode 4. The plasma processor is provided with an electric potential control DC power supply 33 to control the electric potential of this focus ring 9, and so constituted that the lower electrode 4 is supplied with a DC voltage of e.g., −400 to −600 V to control the electric potential of the focus ring 9. This constitution prevents surface arcing from developing along the surface of a substrate to be processed.

An inductively coupled plasma source for a focused charged particle beam system includes a conductive shield within the plasma chamber in order to reduce capacitative coupling to the plasma. The internal conductive shield is maintained at substantially the same potential as the plasma source by a biasing electrode or by the plasma. The internal shield allows for a wider variety of cooling methods on the exterior of the plasma chamber.

Disclosed is an electron beam emission device comprising a housing which defines a space in which electron beams are accelerated, and has an opening at the other side thereof through which the electron beams are emitted; a cathode which is disposed at one side in the housing, and emits the electrons; an anode which is positioned in the housing so as to be spaced apart from the cathode toward the other side, and accelerates the electrons emitted from the cathode; and an insulation holder which insulates a portion between the cathode and the housing, and fixes the cathode, wherein the cathode has a surface which faces the anode and is formed concavely to have a gradient, and a rim of the surface of the cathode, which has the gradient, is formed to be rounded.

In large area plasma processing systems, process gases may be introduced to the chamber via the showerhead assembly which may be driven as an RF electrode. The gas feed tube, which is grounded, is electrically isolated from the showerhead. The gas feed tube may provide not only process gases, but also cleaning gases from a remote plasma source to the process chamber. The inside of the gas feed tube may remain at either a low RF field or a zero RF field to avoid premature gas breakdown within the gas feed tube that may lead to parasitic plasma formation between the gas source and the showerhead. By feeding the gas through an RF choke, the RF field and the processing gas may be introduced to the processing chamber through a common location and thus simplify the chamber design.

In one embodiment, a multi-beam blanking device includes a semiconductor substrate, an insulating film that is disposed on the semiconductor substrate, an antistatic film that is disposed on the insulating film, a plurality of cells each of which is related to a through-hole that penetrate the semiconductor substrate and the insulating film and each of which includes a blanking electrode and a ground electrode that are disposed on the insulating film, and a ground wiring line that is disposed in the insulating film. The antistatic film and the ground wiring line are connected to each other at a joint that extends through the insulating film on the ground wiring line.

A plasma processing apparatus includes an electrostatic chuck that adsorbs a substrate, a relay circuit that turns ON and OFF the supply of voltage to the electrostatic electrode, a plasma generator, and a controller. The controller (a) controls the DC power supply to supply the voltage to the electrostatic electrode, thereby adsorbing the substrate to the electrostatic chuck, (b) controls the relay circuit to turn OFF the supply of the voltage to the electrostatic electrode, thereby bringing the electrostatic electrode into a floating state, (c) controls the plasma generator to start a plasma processing of the substrate, (d) controls the relay circuit to turn ON the supply of the voltage to the electrostatic electrode, thereby acquiring current flowing through the power supply line, and (e) determines an adsorbed state of the substrate based on the current.

A stage apparatus for a particle-beam apparatus is disclosed. A particle beam apparatus may comprise a conductive object and an object table, the object table being configured to support an object. The object table comprises a table body and a conductive coating, the conductive coating being provided on at least a portion of a surface of the table body. The conductive object is disposed proximate to the conductive coating and the table body is provided with a feature proximate to an edge portion of the conductive coating. Said feature is arranged so as to reduce an electric field strength in the vicinity of the edge portion of the conductive coating when a voltage is applied to both the conductive object and the conductive coating.

A plasma probe device includes an antenna unit installed at an opening formed in a wall of a processing chamber or a mounting table through a sealing member configured to seal between a vacuum space and an atmospheric space, an electrode connected to the antenna unit, and a dielectric support portion made of a dielectric material and configured to support the antenna unit from an outer peripheral side. A surface of the antenna unit which is exposed through the opening and separated from a facing surface of the wall or the mounting table facing the antenna unit by a width is depressed from a surface of the wall or the mounting table where the opening is formed, which faces a plasma generation space.

Provided is plasma processing equipment comprising a substrate support, a focus ring disposed along an edge of the upper surface of the substrate support and including a fluid hole passing through a main body, an insulating ring surrounding an outer sidewall of the substrate support and including an inner side surface facing the outer sidewall of the substrate support, an outer side surface, and an upper surface connecting the inner and outer side surfaces, and including upper and lower end portions having different heights, and a connection end portion connecting the upper and lower end portions, a liner surrounding the outer side surface of the insulating ring and a baffle disposed on an upper surface of the liner, wherein a fluid passing through the fluid hole flows along the upper surface, and the baffle generates a pressure difference of the fluid between the upper and lower end portions.