An ion implantation has an ion source and a mass analyzer configured to form and mass analyze an ion beam. A bending element is positioned downstream of the mass analyzer, and respective first and second measurement apparatuses are positioned downstream and upstream of the bending element and configured to determine a respective first and second ion beam current of the ion beam. A workpiece scanning apparatus scans the workpiece through the ion beam. A controller is configured to determine an implant current of the ion beam at the workpiece and to control the workpiece scanning apparatus to control a scan velocity of the workpiece based on the implant current. The determination of the implant current of the ion beam is based, at least in part, on the first ion beam current and second ion beam current.

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.

According to one embodiment, provided is a deflection sensitivity calculation method for calculating deflection sensitivity of a deflector in an electron beam irradiation apparatus that irradiates an irradiation object on a stage with an electron beam by causing the deflector to deflect the electron beam, the deflection sensitivity calculation method including: irradiating an area that covers an adjustment plate with an electron beam by scanning a deflection parameter that controls deflection of the deflector in a predetermined width; detecting a current value detected from the adjustment plate; forming an image corresponding to the detected current value, a number of pixels of the image being known; calculating the number of pixels of a portion corresponding to the adjustment plate in the formed image; and calculating the deflection sensitivity of the deflector.

A beamline device includes a deflection device deflecting an ion beam in a first direction perpendicular to a beam traveling direction by applying at least one of an electric field and a magnetic field to the ion beam. A slit is disposed such that the first direction coincides with a slit width direction. A beam current measurement device is configured to be capable of measuring a beam current at a plurality of measurement positions to be different positions in the first direction. A control device calculates angle information in the first direction on the ion beam by acquiring a plurality of beam current values measured at the plurality of measurement positions to be the different positions in the first direction by the beam current measurement device while changing a deflection amount of the ion beam in the first direction with the deflection device.

An electron microscope includes an electron source, an extraction electrode that extracts an electron beam emitted from the electron source, a monochromator having an energy filter that disperses the electron beam emitted from the electron source based on an energy thereof and an energy selection slit that selects the energy of the electron beam, an incident-side electrode provided between the extraction electrode and the monochromator, and an incident-side electrode controller that controls the incident-side electrode based on a change in a voltage applied to the extraction electrode.

Even in a case where a disturbance is applied from an adjacently disposed power supply circuit or the like, in order to realize a reduction in ripple, a high-voltage power supply device is configured to include a drive circuit, a transformer that boosts an output voltage of the drive circuit, a boost circuit that further boosts a voltage boosted by the transformer, a shield that covers the transformer and the boost circuit, a filter circuit that filters, smoothes, and outputs a high voltage output from the boost circuit, and an impedance loop circuit configured by connection of a plurality of impedance elements into a loop shape. A grounding point of the boost circuit, a grounding point of the shield, and a grounding point of the filter circuit are configured to be grounded via the impedance loop circuit, and this is applied to a high-voltage power supply unit that applies a high voltage to an electron gun of a charged particle beam apparatus.

An apparatus for monitoring of an ion beam. The apparatus may include a processor; and a memory unit coupled to the processor, including a display routine, where the display routine operative on the processor to manage monitoring of the ion beam. The display routine may include a measurement processor to receive a plurality of spot beam profiles of the ion beam, the spot beam profiles collected during a fast scan of the ion beam and a slow mechanical scan of a detector, conducted simultaneously with the fast scan. The fast scan may comprise a plurality of scan cycles having a frequency of 10 Hz or greater along a fast scan direction, and the slow mechanical scan being performed in a direction parallel to the fast scan direction. The measurement processor may also send a display signal to display at least one set of information, derived from the plurality of spot beam profiles.

A system and method for creating a beam current profile that eliminates variations that are not position dependent is disclosed. The system includes two Faraday sensors; one which is moved across the ion beam and a second that remains at or near a certain location. The reference Faraday sensor is used to measure temporal variations in the beam current, while the movable Faraday sensor measures both the position dependent variations and the temporal variations. By combining these measurements, the actual position dependent variations of the scanned ion beam can be determined. This resultant beam current profile can then be used to control the scan speed of the electrostatic or magnetic scanner.

In one embodiment, a multi charged particle beam writing apparatus includes an aperture plate having a plurality of holes to form multiple beams, a blanking aperture array having a plurality of blankers which switch ON-OFF of corresponding respective beams among the multiple beams, a stage on which a writing target substrate is placed, an inspection aperture provided on the stage and that allows one beam among the multiple beams to pass therethrough, a deflector deflecting the multiple beams, a current detector detecting a beam current of each of the multiple beams that has passed through the inspection aperture in a case where the multiple beams are scanned on the inspection aperture, and a control computing machine that generates a beam image based on the detected beam current and detects a defect of the blanking aperture array or the aperture plate based on the beam image.

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.