The purpose of the present invention is to provide a scintillator for a charged particle beam device and a charged particle beam device which achieve both an increase in emission intensity and a reduction in afterglow intensity. This scintillator for a charged particle beam device is characterized by comprising a substrate (13), a buffer layer (14) formed on a surface of the substrate (13), a stack (12) of a light emitting layer (15) and a barrier layer (16) formed on a surface of the buffer layer (14), and a conductive layer (17) formed on a surface of the stack (12) and by being configured such that the light emitting layer (15) contains InGaN, the barrier layer (16) contains GaN, and the ratio b/a of the thickness b of the barrier layer (16) to the thickness a of the light emitting layer (15) is 11 to 25.

The disclosure provides a charged particle detector including a scintillator that emits light with stable intensity and obtains high light emission intensity regardless of an energy of an incident electron. The disclosure provides the charged particle detector including: a first light-emitting part (21) in which a layer containing Ga.sub.1-x-yAl.sub.xIn.sub.yN (where 0≤x<1, 0≤y<1) and a layer containing GaN are alternately laminated; a second light-emitting part (23) in which the layer containing Ga.sub.1-x-yAl.sub.xIn.sub.yN (where 0≤x<1, 0≤y<1) and the layer containing GaN are alternately laminated; and a non-light-emitting part (22) that is interposed between the first light-emitting part (21) and the second light-emitting part (23) (see FIG. 2).

Provided is a charged particle beam device and a charged particle beam device calibration method capable of correcting an influence of characteristic variation and noise with high accuracy. Control units execute a first calibration of correcting a characteristic variation between a plurality of channels in detectors and signal processing circuits by using a setting value of a control parameter for each of the plurality of channels in a state in which a primary electron beam is not emitted. The control units further execute a second calibration of correcting a characteristic variation between the plurality of channels in scintillators or the like by using the setting value of the control parameter for each of the plurality of channels in a state in which the primary electron beam is emitted.

Variations in charged-particle-beam (CPB) source location are determined by scanning an alignment aperture that is fixed with respect to a beam defining aperture in a CPB, particularly at edges of a defocused CPB illumination disk. The alignment aperture is operable to transmit a CPB portion to a secondary emission surface that produces secondary emission directed to a scintillator element. Scintillation light produced in response is directed out of a vacuum enclosure associated with the CPB via a light guide to an external photodetection system.

An electron microscope comprising: A specimen holder, for holding a specimen; An electron beam column, for producing an array of electron beams and concurrently irradiating an array of target areas of said specimen therewith; A scanning assembly, for producing relative scanning motion of said beam array with respect to the specimen; A detector, for detecting radiation emanating from the specimen in response to said irradiation,
wherein said detector is: A backscattered electron detector that can be disposed proximal to the specimen at a side thereof facing said electron beam column; Provided with an array of apertures that allow passage of said electron beams from said column to the specimen; Provided with a functionally sub-divided detection surface that enables segregated detection of a backscattered electron flux produced by each individual beam.

Provided is a multiple electron beam inspection apparatus including: an irradiation source irradiating a substrate with multiple electron beams; a stage on which is cable of mounting the substrate; an electromagnetic lens provided between the irradiation source and the stage, the electromagnetic lens generating a lens magnetic field, the multiple electron beams being capable of passing through the lens magnetic field; an electrostatic lens provided in the lens magnetic field, the electrostatic lens including a plurality of through-holes and a plurality of electrodes, the plurality of through-holes having wall surfaces respectively, each of the multiple electron beams being capable of passing through the corresponding each of the plurality of through-holes, each of the plurality of electrodes provided on each of the wall surfaces of the plurality of through-holes, at least one of the through-holes provided apart from a central axis of trajectory of the multiple electron beams having a spiral shape; and a power source connected to the electrodes.

According to one embodiment, a holder includes a top member, a side member, and a bottom member. The top member has a hole for allowing transmission of a charged particle beam, and the sample is mountable in the hole. The bottom member is provided to overlap with the top member in a plan view. The side member is connected to a part of the top member and a part of the bottom member such that the top member and the bottom member are separated from each other in a cross-sectional view. An opening portion is a region surrounded by the top member, the side member, and the bottom member, and a scintillator is provided in the opening portion.

An electron detector assembly configured for detecting electrons emitted from a sample irradiated by an electron beam, including a scintillator configured with a scintillator layer formed with a scintillating surface. The scintillator layer emits light signals corresponding to impingement of electrons upon the scintillating surface. A light guide plate is coupled to the scintillator layer and includes a peripheral surface. One or more silicon photomultiplier devices are positioned upon the peripheral surface, wherein one or more silicon photomultiplier devices are arranged perpendicularly or obliquely relative to the scintillating surface. The silicon photomultiplier device is configured to yield an electrical signal from an electron impinging upon the scintillator surface.

The objective of the present invention is to provide a charged particle detector and a charged particle beam device with which it is possible to acquire a high luminous output while rapidly eliminating charged particles that are incident to a scintillator. In order to achieve said objective the present invention proposes: a charged particle detector provided with a light-emitting unit including a laminated structure obtained by laminating a GaInN-containing layer and a GaN layer, and provided with a conductive layer that is in contact with the GaInN-containing layer on the charged particle incidence surface side of the laminated structure; and a charged particle beam device.

A method for operating a multi-beam particle beam microscope includes: scanning a multiplicity of particle beams over an object; directing electron beams emanating from impingement locations of the particle beams at the object onto an electron converter; detecting first signals generated by impinging electrons in the electron converter via a plurality of detection elements of a first detection system during a first time period; detecting second signals generated by impinging electrons in the electron converter via a plurality of detection elements of a second detection system during a second time period; and assigning to the impingement locations the signals which were detected via the detection elements of the first detection system during the first time period, for example on the basis of the detection signals which were detected via the detection elements of the second detection system during the second time period.