A charged particle beam writing apparatus includes a number of shots calculation circuit to calculate the number of shots in the case where a deflection region is irradiated with a shot of a charged particle beam, a deflection position correcting circuit to correct a deflection position of the charged particle beam to be shot in the deflection region, depending on the number of shots to be shot in the deflection region, and a deflector to deflect the charged particle beam to a corrected deflected position on the target object.

The scanning charged particle beam microscope according to the present application is characterized in that, in acquiring an image of the FOV (field of view), interspaced beam irradiation points are set, and then, a deflector is controlled so that a charged particle beam scan is performed faster when the charged particle beam irradiates a position on the sample between each of the irradiation points than when the charged particle beam irradiates a position on the sample corresponding to each of the irradiation points (a position on the sample corresponding to each pixel detecting a signal). This allows the effects from a micro-domain electrification occurring within the FOV to be mitigated or controlled.

In one embodiment, a multi charged particle beam writing apparatus includes a plurality of reflective marks disposed on a stage, an inspection aperture member configured to allow one beam to pass therethrough, a first detector detecting a beam current of a beam passed through the inspection aperture member, a second detector detecting charged particles reflected from the reflective marks, a first beam shape calculator generating a beam image based on the beam currents detected by the first detector and calculating a reference beam shape, and a second beam shape calculator calculating a beam shape based on changes in intensity of the reflected charged particles and a position of the stage. The reference beam shape is calculated before writing. During writing, the beam shape based on reflected charged particles is calculated, and variation of the beam shape is added to the reference beam shape.

In one embodiment, a charged particle beam writing apparatus includes a storage unit storing a polynomial and a correction map for correcting deviations of writing positions, a correction processing unit correcting pattern positions in a writing area of a writing target substrate by using the polynomial and correcting the pattern positions in a specific region included in the writing area by using the correction map, and a writing unit writing patterns on a substrate by using a charged particle beam in accordance with the pattern positions corrected by the correction processing unit.

A beam calibration device is presented for calibrating a charged-particle beam in a charged-particle processing apparatus in relation to a positioning of the beam with respect to a target. The beam calibration device includes a detector for the charged particles that are arriving at a registering structure of said device. The beam is deflected from a designated target position towards the device, by means of a lateral initial deflection, thus allowing the beam to impinge on at least one of the registering structures. The beam is scanned over the beam calibration device, thus covering a pre-defined region on this device including the registering structure, and using the detector, an electric current is measured as a current signal and is evaluated, to determine a central relative position of the beam with respect to an optimal position predefined on the beam calibration device surface. Using this optimal position, the beam is deflected back to the designated target position by a reverse lateral deflection which is an inverse of said initial deflection combined with a deflection correction, which represents a correction of the lateral beam position to compensate the central relative position.

System and method for preventing blurring of an image in a scanning direction caused by a signal processing delay of a detector, of a charged particle beam device. The charged particle beam device is configured to calibrate first image data generated based on a detection signal output from a detector when the sample is two-dimensionally scanned with the charged particle beam, to generate second image data, in which the second image data is generated using n first signal profiles each of which corresponds to a signal strength distribution in a first direction and which are extracted from the first image data, and a power spectral density P(f) (f: spatial frequency) of a window function corresponding to the signal processing delay of the detector.

An ion implanter includes an energy analyzer electromagnet provided between an ion source and a processing chamber. The energy analyzer electromagnet includes a Hall probe configured to generate a measurement output in response to a deflecting magnetic field and an NMR probe configured to generate an NMR output. A control unit of the ion implanter includes a magnetic field measurement unit configured to measure the deflecting magnetic field in accordance with a known correspondence between the deflecting magnetic field and the measurement output, a magnetic field determination unit configured to determine the deflecting magnetic field from the NMR output, and a Hall probe calibration unit configured to update the known correspondence by using the deflecting magnetic field determined from the NMR output and a new measurement output of the Hall probe corresponding to the determined deflecting magnetic field.

In one embodiment, a multi charged particle beam writing apparatus includes an aperture plate forming multiple beams, a stage on which a writing target substrate is placed, a stage position detector detecting the position of the stage, an inspection aperture plate provided in the stage, the inspection aperture plate permitting one of the multiple beams to pass through the inspection aperture plate, a deflector deflecting the multiple beams, a current detector detecting a beam current of each of the multiple beams scanned over the inspection aperture plate in X and Y directions and passed through the inspection aperture plate, and a control computer generating a beam image based on the detected beam currents and calculating positions of the beams based on the beam image and the position of the stage.

A charged particle beam writing apparatus includes a number of shots calculation circuit to calculate the number of shots in the case where a deflection region is irradiated with a shot of a charged particle beam, a deflection position correcting circuit to correct a deflection position of the charged particle beam to be shot in the deflection region, depending on the number of shots to be shot in the deflection region, and a deflector to deflect the charged particle beam to a corrected deflected position on the target object.

According to one aspect of the present invention, a charged particle beam apparatus includes fogging charged particle amount distribution operation processing circuitry that operates a fogging charged particle amount distribution by performing convolution integration of a distribution function in which a design distribution center of fogging charged particles is shifted and a exposure intensity distribution in which a design irradiation center of a charged particle beam is not shifted; positional displacement operation processing circuitry that operates a positional displacement based on the fogging charged particle amount distribution; correction processing circuitry that corrects an irradiation position using the positional displacement; and a charged particle beam column including an emission source that emits the charged particle beam and a deflector that deflects the charged particle beam to irradiate a corrected irradiation position with the charged particle beam.