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.

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.

A chicane blanker assembly for a charged particle beam system includes an entrance and an exit, at least one neutrals blocking structure, a plurality of chicane deflectors, a beam blanking deflector, and a beam blocking structure. The entrance is configured to accept a beam of charged particles propagating along an axis. The at least one neutrals blocking structure intersects the axis. The plurality of chicane deflectors includes a first chicane deflector, a second chicane deflector, a third chicane deflector, and a fourth chicane deflector sequentially arranged in series between the entrance and the exit and configured to deflect the beam along a path that bypasses the neutrals blocking structure and exits the chicane blanker assembly through the exit. In embodiments, the chicane blanker assembly includes a two neutrals blocking structures. In embodiments, the beam blocking structure is arranged between the third chicane deflector and the fourth chicane deflector.

Disclosed among other aspects is a charged particle inspection system including an absorbing component and a programmable charged-particle mirror plate arranged to modify the energy distribution of electrons in a beam and shape the beam to reduce the energy spread of the electrons and aberrations of the beam, with the absorbing component including a set of absorbing structures configured as absorbing structures provided on a transparent conductive layer and a method using such an absorbing component and with the programmable charged-particle mirror plate including a set of pixels configured to generate a customized electric field to shape the beam and using such a programmable charged-particle mirror plate.

A charged-particle beam apparatus is provided with a cathode to emit charged particle beams, an anode to propagate the charged particle beams emitted from the cathode in a sample surface direction, an aperture to propagate a charged particle beam passing through an opening at a predetermined position and of a predetermined shape, among the charged particle beams passing through the anode, in the sample surface direction, and a first electrode that is disposed between the anode and the aperture, and is set at a first electric potential of a polarity repelling a polarity of an ion generated due to collision of a charged particle beam.

The invention is directed to a charged particle beam apparatus that enables temperature maintenance in a cooling unit provided inside a vacuum application apparatus using a refrigerant. The charged particle beam apparatus includes a cooling tank that contains a refrigerant for cooling a cooling unit, a cooling pipe that supplies the refrigerant from the cooling tank to the cooling unit, and a unit that leads the refrigerant to liquefy when the refrigerant is biased to a solid.

An apparatus is provided. The apparatus includes a beam current measuring device and a first electrode. The beam current measuring device is retractably movable into an ion beam trajectory so as to measure an ion beam current. The first electrode is disposed immediately upstream of the beam current measuring device in an ion beam transport channel. The first electrode serves both as a suppressor electrode for repelling secondary electrons released from the beam current measuring device, back toward the beam current measuring device, and as a beam optical element other than the suppressor electrode.

Electron-optical systems comprising a particle trap and methods of operating electron-optical systems using a particle trap are disclosed. In one arrangement, a stage supports a sample. An objective lens arrangement projects electrons towards the sample along an electron-beam path. A particle trap comprises an electrode assembly radially outside of the objective lens arrangement and facing the sample. The electrode assembly draws a particle away from a surface of the sample and/or stage as the sample moves relative to the electron-beam path.

Disclosed among other aspects is a charged particle inspection system including an absorbing component and a programmable charged-particle mirror plate arranged to modify the energy distribution of electrons in a beam and shape the beam to reduce the energy spread of the electrons and aberrations of the beam, with the absorbing component including a set of absorbing structures configured as absorbing structures provided on a transparent conductive layer and a method using such an absorbing component and with the programmable charged-particle mirror plate including a set of pixels configured to generate a customized electric field to shape the beam and using such a programmable charged-particle mirror plate.

A charged particle beam apparatus includes a sample chamber; a sample stage; an electron beam column for irradiating a sample with an electron beam; and a focused ion beam column for irradiating the sample with a focused ion beam. The apparatus includes a displacement member having an open/close portion displaceable between an insertion position between a beam emitting end portion of the electron beam column and the sample stage, and a withdrawal position away from the insertion position, and a contact portion provided at a contact position capable of contacting the sample before the beam emitting end portion during operation of the sample stage. A driving unit displaces the displacement member, and a conduction sensor detects whether the sample is in contact with the contact portion.