A beamline ion implanter and a method of operating a beamline ion implanter. A method may include performing an ion implantation procedure during a first time period on a first set of substrates, in a process chamber of the ion implanter, and performing a first pressure-control routine during a second time period by: introducing a predetermined gas to reach a predetermined pressure into at least a downstream portion of the beam-line for a second time period. The method may include, after completion of the first pressure-control routine, performing the ion implantation procedure on a second set of substrates during a third time period.

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.

A multi charged particle beam blanking apparatus includes a substrate, where a plurality of passage holes are formed, to let multi-beams of charged particle beams individually pass through a passage hole concerned; a plurality of reference electrodes, each arranged close to a corresponding passage hole, to be applied with a reference potential, not a ground potential, not via a transistor circuit, in an irradiation region of the whole multi-beams; and a plurality of switching electrodes, arranged at the substrate such that each of the plurality of switching electrodes and a corresponding paired one of the plurality of reference electrodes are opposite each other across a corresponding passage hole, to be applied with the reference potential and a control potential different from the reference potential in a switchable manner.

An ion implantation method includes: irradiating a wafer arranged to meet a predetermined plane channeling condition with an ion beam; measuring a predetermined characteristic on a surface of the wafer irradiated with the ion beam; and evaluating an implant angle distribution of the ion beam by using a result of measurement of the characteristic. The wafer may be arranged so as to include a channeling plane parallel to a predetermined reference plane parallel to a reference trajectory direction of the ion beam incident on the wafer and not to include a channeling plane perpendicular to the reference plane and parallel to the reference trajectory direction.

An electrode system configured to be positioned within a vacuum chamber of an electron-beam metal evaporation and deposition apparatus including a metal slug from which metal is evaporated during operation of the electron-beam metal evaporation and deposition apparatus. The electrode system includes a substantially ring-shaped electrode formed of a conductive material and a plurality of insulating standoffs configured to support the substantially ring-shaped electrode in the vacuum chamber in a position substantially surrounding the metal slug.

An ion implantation method includes acquiring a first data set for setting beam energy of an ion beam output from the high energy multi-stage linear acceleration unit to be a first output value, determining a second data set for setting the beam energy of the ion beam output from the high energy multi-stage linear acceleration unit to be a second output value different from the first output value, based on the first data set, and performing ion implantation by irradiating a workpiece with the ion beam output from the high energy multi-stage linear acceleration unit operating in accordance with the second data set. An acceleration phase of the high frequency accelerator in each of the plurality of stages is the same between the first data set and the second data set, in all of the high frequency accelerators respectively in the plurality of stages.

Provided is a multi charged particle beam writing apparatus, including: an emission unit emitting a charged particle beam; a first aperture substrate having a plurality of first openings, the first aperture being irradiated with the charged particle beam, and the first aperture allowing a portion of the charged particle beam to pass through the plurality of first openings to form multiple beams; a second aperture substrate having a plurality of second openings through which each beam of the multiple beams passes and the second aperture substrate being capable of independently deflecting the each beam of the multiple beams; and a shielding plate provided so as to be insertable to a space between the first aperture substrate and the second aperture substrate and the shielding plate being capable of simultaneously shielding all the multiple beams.

A thin-sample-piece fabricating device is provided with a focused-ion-beam irradiation optical system, a stage, a stage driving mechanism, and a computer. The focused-ion-beam irradiation optical system performs irradiation with a focused ion beam (FIB). The stage holds a sample piece (Q). The stage driving mechanism drives the stage. The computer sets a thin-piece forming region serving as a treatment region, as well as a peripheral section surrounding the entire periphery of the thin-piece forming region, on the sample piece (Q). The computer causes irradiation with the focused ion beam (FIB) from a direction crossing the irradiated face of the sample piece (Q) so as to perform etching treatment such that the thickness of the thin-piece forming region becomes less than the thickness of the peripheral section.

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.

A device for implanting particles in a substrate comprises a particle source and a particle accelerator for generating an ion beam of positively charged ions. The device also comprises a substrate holder and an energy filter, which is arranged between the particle accelerator and the substrate holder. The energy filter is a microstructured membrane with a predefined structural profile for setting a dopant depth profile and/or a defect depth profile produced in the substrate by the implantation. The device also comprises at least one passive braking element for the ion beam. The at least one passive braking element is arranged between the particle accelerator and the substrate holder and is spaced apart from the energy filter.