An apparatus includes a beam scanner applying, during a non-uniform scanning mode, a plurality of different waveforms generating a scan of an ion beam along a scan direction, wherein a given waveform comprises a plurality of scan segments, wherein a first scan segment comprises a first scan rate and a second scan segment comprises a second scan rate different from the first scan rate; a current detector intercepting the ion beam outside of a substrate region and recording a measured integrated current of the ion beam for a given waveform; and a scan adjustment component coupled to the beam scanner and comprising logic to determine: when a beam width of the ion beam along the scan direction exceeds a threshold; and a plurality of current ratios based on the measured integrated current of the ion beam for at least two different waveforms of the plurality of waveforms.

A current quantity measuring method of multi-beams irradiates with a charged particle beam, amplifies an electric signal corresponding to multi-beams passed through a plurality of aperture holes of an aperture member having the plurality of aperture holes to form multi-beams by irradiation with the charged particle beam, receives the electric signal amplified in the minute current measurement unit and counting the number of electrons in the multi-beams, calculates a current quantity of the multi-beams passed through the plurality of aperture holes by using a product of the calculated number of electrons in the multi-beams and elementary charge, and corrects irradiation time of the charged particle beam of each of the plurality of aperture holes on the basis of the calculated current quantity.

An ion implantation apparatus includes a beam scanner that provides reciprocating beam scanning in a beam scanning direction, a beam measurer that measures a beam current intensity distribution in the beam scanning direction at a downstream of the beam scanner, and a controller. The controller includes a scanning waveform preparing unit that determines whether or not a measured beam current intensity distribution measured by the beam measurer with use of a given scanning waveform fits a target non-uniform dose amount distribution, and that, in a case of fitting, correlates the given scanning waveform with the target non-uniform dose amount distribution.

An ion beam profiling system include a beam profiling element, an ion sensitive element electrically isolated from the beam profiling element, an ion source configured to emit an ion beam at the beam profiling element and the ion sensitive element, and a current measuring device coupled to the ion sensitive element. The beam profiling element includes a plate of material have two parallel major surfaces, a first slit aperture extending through the plate of material and having a first longitudinal length extending in a direction parallel to the two parallel major surfaces, and a second slit aperture extending through the plate of material and having a second longitudinal length extending in a direction parallel to the two parallel major surfaces, wherein the first longitudinal length of the first slit aperture is perpendicular to the second longitudinal length of the second slit aperture.

An ion implanter includes a beam scanner that performs a scanning with an ion beam in a scanning direction perpendicular to a traveling direction of the ion beam, and a beam profiler that is disposed downstream of the beam scanner and measures a beam current distribution of the ion beam when the scanning by the beam scanner is performed. The beam profiler includes an aperture array that includes a first aperture and a second aperture, a cup electrode array that is disposed to be fixed with respect to the aperture array, the cup electrode array including a first cup electrode and a second cup electrode, and a plurality of magnets.

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.

It is provided a current measurement module 100 for measuring a current of a primary charged particle beam 123 of a charged particle beam device, the current measurement module 100 including a detection unit 160 configured for detecting secondary and/or backscattered charged particles 127 released on impingement of the primary charged particle beam 123 on a conductive surface 142 of a beam dump 140 of the charged particle beam device.

The invention provides an ion milling device capable of cross-sectional milling on an all-solid-state battery while reducing an occurrence of a short circuit due to a redeposition film. The ion milling device includes a sample stage 5 on which a sample 8 is placed, an ion source 1 configured to emit an unfocused ion beam 4 toward the sample, a stage controller 6 configured to cause the sample stage to perform a swing operation centered on a swing axis S.sub.0 set to be orthogonal to an ion beam center B.sub.0 of the ion beam, and cause the sample stage to perform a sliding operation along a line of intersection between a plane (YZ plane) including the ion beam center and perpendicularly intersecting the swing axis and a sample placement surface of the sample stage, in which the stage controller causes, in a first mode operation, the sample stage to perform the swing operation and the ion source to emit the ion beam to mill the sample, and causes in a second mode operation, the sample stage to perform the sliding operation and the ion source to emit the ion beam to remove sputter particles adhered again to the sample in the first mode operation.

Apparatus and methods are disclosed for particle beam focusing, suitable for use in sample preparation or test environments, including SEM-based nanoprobing platforms. With a particle beam incident on a sample surface, stage current is used as an indicator of spot size. By scanning or searching settings of a working distance control, a control value having maximum (or minimum) stage current is used to set the beam waist at the sample surface. Alternatively, minima (or maxima) of reflected current can be used. Stigmator controls can be adjusted similarly to reduce astigmatism. The scan of control settings can be performed concurrently with sweeping the beam across a region of interest on the sample. Curved sweep patterns can be used. Energy measurements can be used as an alternative to current measurement. Applications to a nanoprobing workflow are disclosed.

Provided is an ion implanter or the like capable of shortening a replacement time of workpieces. An ion implantation method includes (a) deflecting an ion beam by at least one of an electric field and a magnetic field in an irradiation-disabled direction in which a wafer is incapable of being irradiated with the ion beam after a first wafer is irradiated with the ion beam directed in an irradiation-enabled direction in which the wafer is capable of being irradiated with the ion beam; (b) moving the first wafer from an ion implantation position, subsequently to the step (a); (e) disposing a second wafer different from the first wafer at the ion implantation position, subsequently to the step (b); and (f) returning the ion beam from the irradiation-disabled direction to the irradiation-enabled direction, subsequently to the step (e).