A pattern inspection apparatus according to an aspect described herein includes: a stage on which an object to be inspected is capable to be mounted, a multibeam column that irradiates the object to be inspected with multi-primary electron beams, and a multi-detector including a first detection pixel that receives irradiation of a first secondary electron beam emitted after a first beam scanning region of the object to be inspected is irradiated with a first primary electron beam of the multi-primary electron beams and a second detection pixel that receives irradiation of a second secondary electron beam emitted after a second beam scanning region adjacent to the first beam scanning region of the object to be inspected and overlapping with the first beam scanning region is irradiated with a second primary electron beam adjacent to the first primary electron beam of the multi-primary electron beams; a comparison unit that obtains a difference in beam intensity between the first primary electron beam and the second primary electron beam by comparing overlapping portions of a first frame image acquired through entering of the first secondary electron beam into the first detection pixel and a second frame image acquired through entering of the second secondary electron beam into the second detection pixel; and a sensitivity adjustor that adjusts detection sensitivity of the first detection pixel and/or the second detection pixel so as to correct the difference in beam intensity.

The purpose of the present disclosure is to propose a charged particle beam device capable of allowing specifying of a distance between irradiation points for a pulsed beam and a time between irradiation points. Proposed is a charged particle beam device equipped with a beam column which has a scanning deflector for sweeping a beam and directs the beam swept by the scanning deflector onto a sample in pulses, wherein: the distance between irradiation points of the pulsed beam is set such that feature quantities of one or more specific regions of an image obtained on the basis of an output of a detector satisfy a predetermined state; the duration of time between irradiation points for the pulsed beam is changed when in a state in which the set distance between irradiation points is set or in a state in which multiple distances between irradiation points determined on the basis of the specified distance between irradiation points are set; and the beam emission is carried out according to the duration of time between irradiation points whereby the feature quantities of the multiple specific regions of the image obtained on the basis of the output of the detector satisfy the predetermined state.

A scanning electron microscope apparatus including an electron gun configured to generate an electron beam, a focusing lens configured to concentrate the electron beam from the electron gun, an electron detector configured to detect signals emitted from a sample in response to the electron beam incident on the sample, a stage configured to receive the sample thereon, and a focus calibration structure on an upper part of the stage.

A charged particle beam device includes: a charged particle source; an optical system which acts on a charged particle beam emitted from the charged particle source; a control unit which controls the optical system; and a storage unit which stores previous setting values of the optical system. The optical system includes a first optical element and a second optical element for controlling a state of the charged particle beam to be incident on the first optical element. The control unit obtains an initial value of a setting value of the second optical element based on previous setting values of the second optical element; and changes a state of the charged particle beam by changing the setting value of the second optical element from the obtained initial value and obtains the setting value of the second optical element based on the change in the state of the charged particle beam.

Provided is an electron beam observation device that includes: an electron source; an objective lens concentrating an electron beam emitted from the electron source; and a control unit configured to perform control such that a plurality of images is generated by capturing images of a reference sample having a specific pattern, and a frequency characteristic is calculated for each of the plurality of images, in which an image is generated based on a secondary signal generated from a sample due to irradiation of the sample with the electron beam, and the control unit holds the plurality of frequency characteristics.

A charged-particle tool configured to generate a plurality of sub-beams from a beam of charged particles and direct the sub-beams downbeam toward a sample position, the tool charged-particle tool comprising at least three charged-particle-optical components; a detector module; and a controller. Thea detector module is configured to generate a detection signal in response to charged particles that propagate upbeam from the direction of the sample position. The controller is configured to operate the tool in a calibration mode. The charged-particle-optical components include: a charged-particle source configured to emit a beam of charged particles and a beam generator configured to generate the sub-beams. The detection signal contains information about alignment of at least two of the charged-particle-optical components. The charged-particle optical components comprise two or more charged-particle optical elements comprising an array of apertures for which the charged particles may be monitored.

The beamlets in a multi-beam microscopy system are aligned based on coefficients of a fitted aberration model. In particular, an illuminator for directing the beamlets towards the sample is adjusted based on the coefficients to correct the aberrations. The coefficients are obtained based on measured beamlets' positions in the sample plane.

An improved charged particle beam inspection apparatus, and more particularly, a particle beam inspection apparatus including an improved alignment mechanism is disclosed. An improved charged particle beam inspection apparatus may include a second electron detection device to generate one or more images of one or more beam spots of the plurality of secondary electron beams during the alignment mode. The beam spot image may be used to determine the alignment characteristics of one or more of the plurality of secondary electron beams and adjust a configuration of a secondary electron projection system.

The invention relates to Transmission Charged Particle Beam (TCPB) apparatus comprising a sample holder, for holding a sample, a source for producing a beam of charged particles and an illuminator for directing said beam so as to irradiate the sample; The TCPB apparatus comprises an imaging system, for receiving a flux of charged particles transmitted through the sample and directing it onto a sensing device. Further, a controller is provided for controlling at least some operational aspects of the TCPB apparatus. As defined herein, the controller is arranged for receiving calibration data of said TCPB apparatus and using said calibration data for optically aligning said TCPB apparatus. Said calibration data may be obtained in a calibration session, wherein different settings for eucentric focus can be used as a measure of eucentric height, so that the TCPB apparatus can be optically aligned in absence of a sample on the sample holder.

A computing unit generates a to-be-used-in-computation netlist on the basis of a to-be-used-in-calculation device model corresponding to a correction sample, estimates a first application result, on the basis of the to-be-used-in-computation netlist and an optical condition, when a charged particle beam is applied to the correction sample under the optical condition, compares the first application result and a second application result based on a detection signal when the charged particle beam is applied to the correction sample under the optical condition, and corrects the optical condition when the first application result and the second application result differ from each other.