Provided is a particle beam apparatus capable of performing appropriate switching selectively between charged particle beam and neutral particle beam. A particle beam column (19) includes an ion source (41), a condenser lens (52), a charge exchange grid (55), and an objective lens (56). The ion source (41) generates ions. The condenser lens (52) changes focusing of the ion beam so that switching is performed between ion beam and neutral beam as particle beam with which a sample (S) is irradiated. The charge exchange grid (55) converts at least a part of ion beam into neutral particle beam through neutralization. The objective lens (56) is placed downstream of the charge exchange grid (55). The objective lens (56) reduces the ion beam toward the sample (S) when the sample (S) is irradiated with the neutral particle beam as the particle beam.

The present invention provides: a scintillator which is reduced in the intensity of the afterglow, while having increased luminous intensity; and a charged particle radiation apparatus. A scintillator according to the present invention is characterized in that: a base material, a buffer layer, a light emitting part and a first conductive layer are sequentially stacked in this order; the light emitting part contains one or more elements that are selected from the group consisting of Ga, Zn, In, Al, Cd, Mg, Ca and Sr; and a second conductive layer is provided between the base material and the light emitting part.

There is provided a charged particle beam apparatus capable of obtaining a high SN ratio with a small electron irradiation amount. The charged particle beam apparatus includes a charged particle detection device. The charged particle detection device detects an analog pulse waveform signal (110) in a detection of emitted electrons (1 event) when one primary electron enters a sample, converts the analog pulse waveform signal (110) into a digital signal (111), perform a wave height discrimination (112) with the use of a unit peak corresponding electron, and outputs the digital signal (111) as a multilevel count value.

The purpose of the present invention is to reduce the amount of charged particles that are lost by colliding with the interior of a column of a charged particle beam device, and detect charged particles with high efficiency. To achieve this purpose, proposed is a charged particle beam device provided with: an objective lens that focuses a charged particle beam; a detector that is disposed between the objective lens and a charged particle source; a deflector that deflects charged particles emitted from a sample such that the charged particles separate from the axis of the charged particle beam; and a plurality of electrodes that are disposed between the deflector and the objective lens and that form a plurality of electrostatic lenses for focusing the charged particles emitted from the sample on a deflection point of the deflector.

Provided is a charged particle beam device capable of observing the interior and the surface of a sample in a simple manner. This charged particle beam device operates in a transmitted charged particle image mode and a secondary charged particle image mode. In the transmitted charged particle image mode, a transmitted charged particle image is produced on the basis of a detection signal (512) associated with light emitted from a light-emitting member (500) that emits light upon being irradiated with transmitted charged particles transmitted through the interior of a sample (6). In the secondary charged particle image mode, a secondary charged particle image is produced on the basis of a detection signal (518) caused by reflected charged particles or secondary charged particles (517) from the sample (6).

A multiple particle beam system with a mirror mode of operation, a method for operating a multiple particle beam system with a mirror mode of operation and an associated computer program product are disclosed. The multiple particle beam system can be operated in different mirror modes of operation which allow the multiple particle beam system to be inspected and recalibrated thoroughly. A detection system configured to operate in a first detection mode and/or in a second detection mode is used for the analysis.

Proposed is a charged particle beam apparatus for the purpose of detecting a charged particle emitted from a sample in a specific direction by discriminating between the charged particle and a charged particle emitted in another direction. As one aspect of achieving the above purpose, proposed is a charged particle beam apparatus including an objective lens configured to focus a beam emitted from a charged particle source, a detector (8) configured to detect at least one of a first charged particle (23) emitted from a sample by irradiating the sample with the beam and a second charged particle emitted from a charged particle collided member by causing the first charged particle to collide with the charged particle collision member disposed on a trajectory of the first charged particle, and an electrostatic lens (12) including a plurality of electrodes disposed between the objective lens and the detector, in which the electrostatic lens is a Butler type.

Provided is a charged particle beam apparatus which includes a charged particle source, a sample table on which a sample is placed, a charged particle beam optical system that includes an objective lens and emits a charged particle beam emitted from the charged particle source onto the sample, a plurality of detectors which detect secondary particles emitted from the sample when being irradiated with the charged particle beam, and a rotation member which magnetically, electrically, or mechanically changes a detected azimuth angle of the secondary particles emitted from the sample.

An electron beam device obtains contrast reflecting an electronic state of a sample with high sensitivity. The device includes an electron optical system which emits an electron beam to a sample and detects electrons emitted from the sample; a light pulse emission system that emits a light pulse to the sample; a synchronization processing unit that samples the emitted electrons; an image signal processing unit which forms an image by a detection signal output based upon the emitted electrons detected by the electron optical system; and a device control unit for setting a control condition of the electron optical system. The device control unit sets a sampling frequency for detection sampling of the emitted electrons to be greater than a value obtained by dividing the number of emissions of the light pulse per unit pixel time by the unit pixel time.

Even when the amount of overlay deviation between patterns located in different layers is large, correct measurement of the amount of overlay deviation is stably performed. The charged particle beam device includes a charged particle beam irradiation unit that irradiates a sample with a charged particle beam, a first detection unit that detects secondary electrons from the sample, a second detection unit that detects backscattered electrons from the sample, and an image processing unit that generates a first image including an image of a first pattern located on the surface of the sample based on an output of the first detection unit, and generates a second image including an image of a second pattern located in a lower layer than the surface of the sample based on an output of the second detection unit. A control unit adjusts the position of a measurement area in the first image based on a first template image for the first image, and adjusts the position of a measurement area in the second image based on a second template image for the second image.