Abstract: A method of processing a wafer includes a plasma activation processing step of performing plasma processing on at least either one surface of a first wafer or one surface of a second wafer to activate the surface, a bonded wafer forming step of forming a bonded wafer by provisionally joining the first wafer and the second wafer, a modified layer forming step of forming modified layers in an annular pattern inside the first wafer by applying a laser beam of a wavelength having transmissivity for the first wafer, an outer peripheral region removal step of removing an outer peripheral region of the first wafer by applying an external force, an anneal processing step of performing anneal processing to increase joint strength of the bonded wafer, and a grinding step of grinding the first wafer to thin it to a finish thickness.

Abstract: 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.

Abstract: 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.

Abstract: A measurement device that comprises a photoelectric conversion element and a signal processing part that receives, from the photoelectric conversion element, detected pulses that include dark pulses and signal pulses that are outputted in accordance with inputted photons. The signal processing part performs amplitude discrimination on the detected pulses on the basis of a pre-acquired dark pulse amplitude distribution for the photoelectric conversion element.

Abstract: There is provided a technique capable of reducing deterioration of a back scattered electron (BSE) detector caused by a dark pulse. Charged particle beam apparatus includes: a plurality of BSE detectors configured to detect a BSE from a sample; and a controller. The controller acquires, within a period, a first peak time of a first peak included in an output signal from a first BSE detector among the plurality of BSE detectors, and a second peak time of a second peak included in an output signal from a second BSE detector other than the first BSE detector among the plurality of BSE detectors, determines, when the second peak is present where a time difference between the first peak time and the second peak time is within a threshold value, that the first peak is caused by the BSE, and determines, when the second peak is not present where the time difference is within the threshold value, that the first peak is caused by the dark pulse.

Abstract: The invention is directed to suppress charge of a region of interest or damage in the region of interest caused by blanking. A charged particle beam device includes: a deflector configured to scan a region of interest with a beam emitted from a beam source; a second deflector configured to retract the beam to outside of the region of interest after scanning the region of interest with the beam; and one or more computer systems including one or more processors configured to execute a program stored in a storage medium, in which the one or more computer systems determine a retraction direction or a retraction position of the beam (Step S402) based on a scanning direction of the beam in the region.

Abstract: A tape cassette includes a recess formed on a part of a side wall of a cassette case, an arm portion, a roller partly exposed from the tape cassette, a first protrusion including a first leading end, and a second protrusion including a second leading end. The first leading end and the second leading end protrudes toward first side. The first leading end is positioned on a first virtual line or further to the first side than the first virtual line. The first virtual line connects an exposed part of an outer peripheral surface of the roller with a connection portion between the recess and a wall comprising the arm portion. The second leading end is positioned further to the first side than a second virtual line. The second virtual line connects the exposed part of the outer peripheral surface of the roller with the first leading end.

Abstract: Provided is a charged particle beam device that can impart a function of an energy filter to even a small BSE detector. The charged particle beam device includes a fluorescent substance that converts charged particles generated by irradiation of a sample with a charged particle beam into light; a detector that detects the light emitted from the fluorescent substance; a light guide element for guiding the light from the fluorescent substance to the detector; a light amount adjuster that adjusts the amount of light that is received by the detector through the fluorescent substance and the light guide element; and a control unit that controls the light amount adjuster.

Abstract: A charged particle beam apparatus covering a wide range of detection angles of charged particles emitted from a sample includes an objective lens for converging charged particle beams emitted from a charged particle source and a detector for detecting charged particles emitted from a sample. The objective lens includes inner and outer magnetic paths which are formed so as to enclose a coil. A first inner magnetic path is disposed at a position opposite to an optical axis of the charged particle beams. A second inner magnetic path, formed at a slant with respect to the optical axis of the charged particle beams, includes a leading end. A detection surface of the detector is disposed at the outer side from a virtual straight line that passes through the leading end and that is parallel to the optical axis of the charged particle beams.

Abstract: A charged particle beam apparatus using a light guide that improves light utilization efficiency includes a detector including a scintillator for emitting light when a charged particle is incident, a light receiving element, and a light guide for guiding the light from the scintillator to the light receiving element. The light guide includes: an incident surface that faces a light emitting surface of the scintillator and to which the light emitted by the scintillator is incident; an emitting surface that is configured to emit light; and a reflecting surface that is inclined with respect to the incident surface so that the light from the incident surface is reflected toward the emitting surface. The emitting surface is smaller than the incident surface. A slope surface is provided between the incident surface and the emitting surface, faces the reflecting surface, and is inclined with respect to the incident surface.

Abstract: 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.

Abstract: A tape cassette includes a cassette case, a tape roll, a print tape wound around the tape roll, a ribbon roll, an ink ribbon wound around the ribbon roll, a recess, an arm portion, and a guide. The print tape and the ink ribbon are conveyed inside the cassette case and the arm portion. The arm portion includes a discharge port to discharge the print tape and the ink ribbon. The guide is provided at a position downstream of the discharge port, on a conveyance path of the print tape and the ink ribbon. A first end of the guide includes a roller members configured to rotate around a shaft extending in the up-down direction. The guide is configured to guide the ink ribbon, by the first end coming into contact with the ink ribbon, to a winding path branching from the conveyance path and toward the ribbon winding spool.

Abstract: A tape cassette includes a recess formed on a part of a side wall of a cassette case, an arm portion, a roller partly exposed from the tape cassette, a first protrusion including a first leading end, and a second protrusion including a second leading end. The first leading end and the second leading end protrudes toward first side. The first leading end is positioned on a first virtual line or further to the first side than the first virtual line. The first virtual line connects an exposed part of an outer peripheral surface of the roller with a connection portion between the recess and a wall comprising the arm portion. The second leading end is positioned further to the first side than a second virtual line. The second virtual line connects the exposed part of the outer peripheral surface of the roller with the first leading end.

Abstract: A charged particle beam apparatus using a light guide that improves light utilization efficiency includes a detector including a scintillator for emitting light when a charged particle is incident, a light receiving element, and a light guide for guiding the light from the scintillator to the light receiving element. The light guide includes: an incident surface that faces a light emitting surface of the scintillator and to which the light emitted by the scintillator is incident; an emitting surface that is configured to emit light; and a reflecting surface that is inclined with respect to the incident surface so that the light from the incident surface is reflected toward the emitting surface. The emitting surface is smaller than the incident surface. A slope surface is provided between the incident surface and the emitting surface, faces the reflecting surface, and is inclined with respect to the incident surface.

Abstract: A charged particle beam apparatus using a light guide that improves light utilization efficiency includes a detector including a scintillator for emitting light when a charged particle is incident, a light receiving element, and a light guide for guiding the light from the scintillator to the light receiving element. The light guide includes: an incident surface that faces a light emitting surface of the scintillator and to which the light emitted by the scintillator is incident; an emitting surface that is configured to emit light; and a reflecting surface that is inclined with respect to the incident surface so that the light from the incident surface is reflected toward the emitting surface. The emitting surface is smaller than the incident surface. A slope surface is provided between the incident surface and the emitting surface, faces the reflecting surface, and is inclined with respect to the incident surface.

Abstract: 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.

Abstract: 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.

Abstract: Provided is a charged particle beam device capable of detecting signal charged particles in a wide range of elevation angles from a large elevation angle to a small elevation angle and distinguishing detection signals between backscattered charged particles and secondary charged particles regardless of distribution of the signal charged particles. The charged particle beam device according to the disclosure includes a first detector that detects the secondary charged particles or the backscattered charged particles and a second detector that detects tertiary charged particles generated from the first detector, and generates an observation image of a sample using a signal value obtained by subtracting at least a part of a second detection signal output by the second detector from a first detection signal output by the first detector, or subtracting at least a part of the first detection signal from the second detection signal.

Abstract: A measurement device that comprises a photoelectric conversion element and a signal processing part that receives, from the photoelectric conversion element, detected pulses that include dark pulses and signal pulses that are outputted in accordance with inputted photons. The signal processing part performs amplitude discrimination on the detected pulses on the basis of a pre-acquired dark pulse amplitude distribution for the photoelectric conversion element.

Abstract: The present disclosure pertains to a method, a system, and a computer-readable medium for highly precisely measuring the depth of a recess formed in a sample even when, inter alia, the material or pattern density of the sample differs.