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 inspection device for inspecting a surface of an inspection object using a beam includes a beam generator capable of generating one of either charge particles or an electromagnetic wave as a beam, a primary optical system capable of guiding and irradiating the beam to the inspection object supported within a working chamber, a secondary optical system capable of including a first movable numerical aperture and a first detector which detects secondary charge particles generated from the inspection object, the secondary charge particles passing through the first movable numerical aperture, an image processing system capable of forming an image based on the secondary charge particles detected by the first detector; and a second detector arranged between the first movable numerical aperture and the first detector and which detects a location and shape at a cross over location of the secondary charge particles generated from the inspection object.

An ion implanter includes an ion source configured to generate an ion beam including an ion of a nonradioactive nuclide, a beamline configured to support an ion beam irradiated target, and a controller configured to calculate an estimated radiation dosage of a radioactive ray generated by a nuclear reaction between the ion of the nonradioactive nuclide incident into the ion beam irradiated target and the nonradioactive nuclide accumulated in the ion beam irradiated target as a result of ion beam irradiation performed previously.

There is provided an electron microscope in which a crossover position can be kept constant. The electron microscope (100) includes: an electron source (110) for emitting an electron beam; an acceleration tube (170) having acceleration electrodes (170a-170f) and operative to accelerate the electron beam; a first electrode (160) operative such that a lens action is produced between this first electrode (160) and the initial stage of acceleration electrode (170a); an accelerating voltage supply (112) for supplying an accelerating voltage to the acceleration tube (170); a first electrode voltage supply (162) for supplying a voltage to the first electrode (160); and a controller (109b) for controlling the first electrode voltage supply (162). The lens action produced between the first electrode (160) and the initial stage of acceleration electrode (170a) forms a crossover (CO2) of the electron beam. The controller (109b) controls the first electrode voltage supply (162) such that, if the accelerating voltage is modified, the ratio between the voltage applied to the first electrode (160) and the voltage applied to the initial stage of acceleration electrode (170a) is kept constant.

An ion implantation apparatus includes an ion source that is capable of generating a calibration ion beam including a multiply charged ion which has a known energy corresponding to an extraction voltage, an upstream beamline that includes amass analyzing magnet and a high energy multistage linear acceleration unit, an energy analyzing magnet, a beam energy measuring device that measures an energy of the calibration ion beam downstream of the energy analyzing magnet, and a calibration sequence unit that produces an energy calibration table representing a correspondence relation between the known energy and the energy of the calibration ion beam measured by the beam energy measuring device. An upstream beamline pressure is adjusted to a first pressure during an ion implantation process, and is adjusted to a second pressure higher than the first pressure while the energy calibration table is produced.

A novel composition, system and method for improving beam current during boron ion implantation are provided. In a preferred aspect, the boron ion implant process involves utilizing B2H6, 11BF3 and H2 at specific ranges of concentrations. The B2H6 is selected to have an ionization cross-section higher than that of the BF3 at an operating arc voltage of an ion source utilized during generation and implantation of active hydrogen ions species. The hydrogen allows higher levels of B2H6 to be introduced into the BF3 without reduction in F ion scavenging. The active boron ions produce an improved beam current characterized by maintaining or increasing the beam current level without incurring degradation of the ion source when compared to a beam current generated from conventional boron precursor materials.

A purpose of the present invention is to provide a charged particle beam device that suppresses an off-axis amount when a field of view moves, said move causing an aberration, and allows large field of view moves to be carried out. In order to achieve the above-mentioned purpose, this charged particle beam device is provided with an objective lens and deflectors for field of view moves, said deflectors deflecting a charged particle beam, and is further provided with an accelerating tube positioned between the objective lens and the deflectors for field of view moves, a power source that applies a voltage to the accelerating tube, and a control device that controls the voltage to be applied to the power source in response to the deflection conditions of the deflectors for field of view moves.

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.

An apparatus and method for processing a workpiece with a beam is described. The apparatus includes a vacuum chamber having a beam-line for forming a particle beam and treating a workpiece with the particle beam, and a scanner for translating the workpiece through the particle beam. The apparatus further includes a scanner control circuit coupled to the scanner, and configured to control a scan property of the scanner, and a beam control circuit coupled to at least one beam-line component, and configured to control the beam flux of the particle beam according to a duty cycle for switching between at least two different states during processing.

An ion implantation apparatus includes: a multistage linear acceleration unit including a plurality of stages of high-frequency resonators and a plurality of stages of focusing lenses; a first beam measuring unit disposed in the middle of the multistage linear acceleration unit and configured to allow passage of a beam portion adjacent to a center of a beam trajectory and measure a current intensity of another beam portion blocked by an electrode body outside a vicinity of the center of the beam trajectory; a second beam measuring unit disposed downstream of the multistage linear acceleration unit and configured to measure a current intensity of an ion beam exiting from the multistage linear acceleration unit; and a control device configured to adjust a control parameter of the plurality of stages of focusing lenses based on measurement results of the first and second beam measuring units.