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.

Embodiments of deposition rings for use in a process chamber are provided herein. In some embodiments, a deposition ring includes: an annular body; an inner wall extending upward from an inner portion of the annular body; and an outer wall extending upward form an outer portion of the annular body to define a large deposition cavity between the inner wall and the outer wall, wherein a width of the large deposition cavity is about 0.35 inches to about 0.60 inches, wherein the outer wall includes an outer ledge and an inner ledge raised with respect to the outer ledge.

Provided is an ion beam system including a gas field ionization ion source which can obtain a high current sufficient for processing and stabilize an ion beam current. The ion beam system includes a gas field ionization ion source which includes: a vacuum vessel; an emitter tip holder disposed in the vacuum vessel; an emitter tip connected to the emitter tip holder; an extraction electrode opposed to the emitter tip; a gas supply portion for supplying a gas to the emitter tip; and a cold transfer member disposed in the vacuum vessel and transferring cold energy to the emitter tip holder. The cold transfer member has its surface covered with a heat insulating material in order to prevent the gas condensation.

An ion source for an ion implantation system is configured to form an ion beam from a predetermined species along a beamline, where the ion beam is at an initial energy. A deceleration component is configured to decelerate the ion beam to a final energy that is less than the initial energy. A workpiece support is configured to support a workpiece along a workpiece plane downstream of the deceleration component along the beamline. A beamline component is positioned downstream of the deceleration component along the beamline. The beamline component has a feature that is at least partially impinged by the ion beam, and where the feature has a surface having a predetermined angle of incidence with respect to the ion beam. The predetermined angle of incidence provides a predetermined sputter yield of the ion beam at the final energy that mitigates deposition of the ion species on the beamline component.

Provided is a charged particle beam device capable of reducing scattering of a foreign substance collected by a foreign substance collecting unit. The charged particle beam device includes: a sample chamber in which a sample is to be disposed; and a charged particle beam source configured to irradiate the sample with a charged particle beam. The charged particle beam device further includes: a foreign substance attachment/detachment unit from or to which a foreign substance is to detach or attach; and a foreign substance collecting unit provided in the sample chamber and configured to collect a foreign substance dropped from the foreign substance attachment/detachment unit. An opening through which the foreign substance passes is provided in an upper end portion of the foreign substance collecting unit. An area of the opening is smaller than a horizontal cross-sectional area of an internal space of the foreign substance collecting unit.

An e-beam device includes a cold-field emission source to emit electrons and an extractor electrode to be positively biased with respect to the cold-field emission source to extract the electrons from the cold-field emission source. The extractor electrode has a first opening for the electrons. The e-beam device also includes a mirror electrode with a second opening for the electrons. The mirror electrode is configurable to be positively biased with respect to the extractor electrode during a first mode of operation and to be negatively biased with respect to the extractor electrode during a second mode of operation. The extractor electrode is disposed between the cold-field emission source and the mirror electrode. The e-beam device further includes an anode to be positively biased with respect to the extractor electrode and the cold-field emission source. The mirror electrode is disposed between the extractor electrode and the anode.

The invention relates to a device (100) for reducing ice contamination of a sample (S) in a chamber (210) of a focused ion beam milling apparatus (200), wherein the device (100) comprises a body (110) configured to be cooled to cryogenic temperatures, wherein the body (110) comprises an aperture (111), which is configured such that an ion beam (I) generated by an ion source (220) can pass from the ion source (220) through the aperture (111) to the sample (S), wherein the body (110) comprises a recess (112), wherein said aperture (111) is arranged in the recess (112).

The invention further relates to a focused ion beam milling apparatus (200) and a method for focused ion beam milling of a sample (S).

A cleaning tool for cleaning a glass surface of an accelerator column is disclosed. The cleaning tool includes a shaft including a first end and a second end; a foam body located at the first end of the shaft; and a mounting bracket coupled to the first end of the shaft, the mounting bracket receiving the foam body. An outer circumference of the foam body includes a textured cleaning surface for contacting the glass surface of the accelerator column.

A processing chamber may include a gas distribution member, a metal ring member below the gas distribution member, and an isolating assembly coupled with the metal ring member and isolating the metal ring member from the gas distribution member. The isolating assembly may include an outer isolating member coupled with the metal ring member. The outer isolating member may at least in part define a chamber wall. The isolating assembly may further include an inner isolating member coupled with the outer isolating member. The inner isolating member may be disposed radially inward from the metal ring member about an central axis of the processing chamber. The inner isolating member may define a plurality of openings configured to provide fluid access into a radial gap between the metal ring member and the inner isolating member.

The present invention relates to an apparatus for examining and/or processing a sample, said apparatus comprising: (a) a scanning particle microscope for providing a beam of charged particles, which can be directed on a surface of the sample; and (b) a scanning probe microscope with a deflectable probe; (c) wherein a detection structure is attached to the deflectable probe.