A multi-beam pattern definition device for use in a particle-beam processing or inspection apparatus, which is irradiated with a beam of electrically charged particles and allows passage of the beam through a plurality of apertures to form corresponding beamlets, comprises an aperture array device in which said apertures are realized according to several sets of apertures arranged in respective aperture arrangements, and an absorber array device having a plurality of openings configured for the passage of at least a subset of beamlets that are formed by the apertures. The absorber array device comprises a plurality of openings corresponding to one of the aperture arrangements of the aperture array device, whereas it includes a charged-particle absorbing structure comprising absorbing regions surrounded by elevated regions and configured to absorb charged particles impinging thereupon at locations corresponding to apertures of the other aperture arrangements of the aperture array device, effectively confining the effects of irradiated particles and electric charge therein.

The disclosure relates to an electron-optical module of an electron-optical apparatus. The electron-optical module comprises a vacuum chamber, a high voltage shielding arrangement located within the vacuum chamber, and an aperture array configured to form a plurality of beamlets from an electron beam and located within the high voltage shielding arrangement. Wherein the electron-optical module can be configured to be removable from the electron-optical apparatus.

Provided is an ion milling apparatus capable of enhancing reproducibility of an ion distribution. The ion milling apparatus includes: an ion source 101; a sample stage 102 on which a sample to be processed by being irradiated with an unfocused ion beam from the ion source 101 is placed; and a measurement member holding unit 106 that holds an ion beam current measurement member 105. A covering material 120 is provided so as to cover at least a surface of the measurement member holding unit 106 and the sample stage 102 facing the ion source 101. A material of the covering material 120 contains, as a main component, an element having an atomic number smaller than that of an element of a material of a structure on which the covering material is provided. The ion beam current measurement member 105 is moved in an irradiation range of the ion beam on a trajectory, which is located between the ion source and the sample stage, in a state where the ion beam is output from the ion source 101 under a first irradiation condition, and an ion beam current flowing when the ion beam current measurement member 105 is irradiated with the ion beam is measured.

In one embodiment, a multi charged particle beam writing method includes forming a multi charged particle beam with which a substrate serving as a writing target is irradiated, deflecting the multi charged particle beam to a position with a predetermined deflection offset added so that deflection voltages respectively applied to a plurality of electrodes of an electrostatic positioning deflector does not include a state where all the deflection voltages are zero, and irradiating the substrate with the multi charged particle beam. A positive common voltage is added to the deflection voltages which are applied to the respective electrodes of the electrostatic positioning deflector.

A method includes forming a resist pattern, the resist pattern having trenches oriented lengthwise along a first direction and separated by resist walls along both the first direction and a second direction perpendicular to the first direction. The method further includes loading the resist pattern into an ion implanter so that a top surface of the resist pattern faces an ion travel direction, and tilting the resist pattern so that the ion travel direction forms a tilt angle with respect to an axis perpendicular to the top surface of the resist pattern. The method further includes rotating the resist pattern around the axis to a first position; implanting ions into the resist walls with the resist pattern at the first position; rotating the resist pattern around the axis by 180 degrees to a second position; and implanting ions into the resist walls with the resist pattern at the second position.

An ion gun according to one embodiment of the present invention has an anode, a cathode having a first portion and a second portion that face the anode, and a magnet that creates a spatial magnetic field between the first portion and the second portion. An annular gap including a curved portion is provided between the first portion and the second portion of the cathode. The magnet creates lines of magnetic field having the bottom inside with respect to the sectional center line of the gap between the first portion and the second portion of the curved portion.

Embodiments relate to a grid short clearing system is provided for gridded ion beam sources used in industrial applications for materials processing systems that reduces grid damage during operation. In various embodiments, the ion source is coupled to a process chamber and a grid short clearing system includes methods for supplying a gas to the process chamber and setting the gas pressure to a predetermined gas pressure in the range between 50 to 750 Torr, applying an electrical potential difference between each adjacent pair of grids using a current-limited power supply, and detecting whether or not the grid shorts are cleared. The electrical potential difference between the grids is at least 10% lower than the DC electrical breakdown voltage between the grids with no contaminants.

Substrate processing systems, such as ion implantation systems, deposition systems and etch systems, having textured silicon liners are disclosed. The silicon liners are textured using a chemical treatment that produces small features, referred to as micropyramids, which may be less than 20 micrometers in height. Despite the fact that these micropyramids are much smaller than the textured features commonly found in graphite liners, the textured silicon is able to hold deposited coatings and resist flaking. Methods for performing preventative maintenance on these substrate processing systems are also disclosed.

An arc chamber has a liner operably coupled to body. The liner has a second surface recessed from a first surface and a hole having a first diameter. The liner has a liner lip extending upwardly from the second surface toward the first surface that surrounds the hole and has a second diameter. An electrode has a shaft and head. The shaft has a third diameter that is less than the first diameter and passes through the body and hole and is electrically isolated from the liner by an annular gap. The head has a fourth diameter and a third surface having an electrode lip extending downwardly from the third surface toward the second surface. The electrode lip has a fifth diameter that is between the second and fourth diameters. A spacing between the liner lip and electrode lip defines a labyrinth seal and generally prevents contaminants from entering the annular gap. The shaft has an annular groove configured to accept a boron nitride seal.

The invention relates to charged particle beam generator comprising a charged particle source for generating a charged particle beam, a collimator system comprising a collimator structure with a plurality of collimator electrodes for collimating the charged particle beam, a beam source vacuum chamber comprising the charged particle source, and a generator vacuum chamber comprising the collimator structure and the beam source vacuum chamber within a vacuum, wherein the collimator system is positioned outside the beam source vacuum chamber. Each of the beam source vacuum chamber and the generator vacuum chamber may be provided with a vacuum pump.