Abstract: An object of the invention is to provide an electron microscope capable of obtaining a sufficient energy resolution without forming a long drift space and capable of attaining high energy discrimination detection performance with approximately the same device size as in the related art. The electron microscope according to the invention includes a pulsed electron emission mechanism configured to emit an electron beam in a pulsed manner, and discriminates energy of signal electrons by discriminating the signal electrons, which are emitted from a sample by irradiating the sample with the electron beam, according to a time of flight (see FIG. 2).

Abstract: A charged particle beam device which prevents an appearance of a shading contrast due to azimuth discrimination and obtains a clear magnetic domain contrast image with a high resolution and a high throughput. The charged particle beam device includes an electron beam source; a sample stage; an objective lens configured to focus electron beams on a sample; a detector that is mounted on a charged particle beam source side with respect to the objective lens and separately detects secondary electrons emitted in azimuth angle ranges of two or more different azimuths for the same observation region; an image processing and image management device including an image processing unit configured to perform synthesis after performing shading correction and contrast adjustment on an image obtained by detecting a first emission azimuth and an image obtained by detecting a second emission azimuth; an image database; and an image display unit.

Abstract: An electron beam emitted from a photoexcited electron gun is increased in luminance. An electron gun 15 includes: a photocathode 1 including a substrate 11 and a photoelectric film 10; a light source 7 that emits pulsed excitation light; a condenser lens 2 that focuses the pulsed excitation light toward the photocathode; and an extractor electrode 3 that faces the photocathode and that accelerates an electron beam generated from the photoelectric film by focusing the pulsed excitation light by the condenser lens, transmitting the pulsed excitation light through the substrate of the photocathode, and causing the pulsed excitation light to be incident on the photocathode. The pulsed excitation light is condensed at different timings at different positions on the photoelectric film of the photocathode.

Abstract: The invention provides a charged particle beam device that prevents a leakage of an unnecessary magnetic field to a trajectory of a charged particle beam with which a sample is irradiated in a sample observation according to a boosting method. The charged particle beam device includes: a charged particle source configured to generate the charged particle beam with which the sample is irradiated; an object lens configured to generate the magnetic field for focusing the charged particle beam; and a boosting electrode that is provided inside the object lens and to which a voltage for accelerating the charged particle beam is applied. The boosting electrode is formed of a magnetic material.

Abstract: An activation mechanism is provided in an activation region of an electron gun, and includes a light source device 3 configured to irradiate a photocathode with excitation light, a heat generating element, an oxygen generation unit configured to generate oxygen by heating the heat generating element, and an emission current meter configured to monitor an emission current generated by electron emission when the photocathode 1 is irradiated with the excitation light from the light source device. In a surface activation process, the photocathode is irradiated with the excitation light from the light source device, an emission current amount of the photocathode is monitored by the emission current meter, the heat generating element is heated to generate oxygen by the oxygen generation unit, and the heating of the heat generating element is stopped when the emission current amount of the photocathode satisfies a predetermined stop criterion.

Abstract: A scanning electron microscope includes a spin detector configured to measure secondary electron spin polarization of secondary electrons emitted from the sample, and an analysis device configured to analyze secondary electron spin polarization data measured by the spin detector. The analysis device evaluates the strain in the sample by calculating a difference in the secondary electron spin polarization data of adjacent pixels.

Abstract: To implement a charged particle beam device including an iron thin film spin detector. The charged particle beam device includes: a charged particle column 201 configured to perform scanning on a sample 203 with a charged particle beam 202; a spin detector including an iron thin film 207, a plurality of coils 208 configured to magnetize the iron thin film, a conveying lens 206 configured to focus, on the iron thin film, secondary electrons 204 emitted from the sample due to irradiation of the charged particle beam, and an electron detector 210 configured to detect backscattered electrons 209 emitted due to the iron thin film being irradiated with the secondary electrons; and a control unit 217 configured to control switching of a magnetization direction of the iron thin film in synchronization with scanning of one line with the charged particle beam from the charged particle column.

Abstract: Provided is a sample image observation device including an SEM and a control system configured to control the SEM. An observation region of a sample is divided into a plurality of sections, and restoration processing is performed on an image which is acquired by irradiating each section with a sparse electron beam, based on scanning characteristics in the section. A reduction in quality of a restored image due to a beam irradiation position deviation caused by a scanning response is prevented and restoration with high accuracy and high throughput under a condition for preventing sample damage is possible.

Abstract: The present invention provides a charged particle beam apparatus capable of efficiently reducing the effect of a residual magnetic field when SEM observation is performed. The charged particle beam apparatus according to the present invention includes a first mode for passing a direct current to a second coil after turning off a first coil, and a second mode for passing an alternating current to the second coil after turning off the first coil.

Abstract: The electron gun is provided with a first anode electrode and a second anode electrode to generate an acceleration and deceleration electric field. A lens electric field makes it possible to irradiate a sample with an electron beam emitted from a part outside an optical axis of the photoelectric film without being blocked by a differential exhaust diaphragm. A wide range of electron beams off-optical axis can be used even in a high-brightness photocathode that requires high vacuum. As a result, the photoelectric film and the electron gun can be extended in life, can be stabilized, and can be increased in brightness. Further, it is possible to facilitate a control of emitting electron beams from a plurality of positions on the photoelectric film, a timing control of emitting electron beams from a plurality of positions, a condition control of an electron beam in an electron microscope using electron beams.

Abstract: The present invention realizes a composite charged particle beam apparatus capable of suppressing a leakage magnetic field from a pole piece forming an objective lens of an SEM with a simple structure. The charged particle beam apparatus according to the present invention obtains an ion beam observation image while passing a current to a first coil constituting the objective lens, and performs an operation of reducing the image shift by passing a current to a second coil with a plurality of current values, and determines a current to be passed to the second coil based on a difference between the operations.

Abstract: The invention provides a charged particle beam device that prevents a leakage of an unnecessary magnetic field to a trajectory of a charged particle beam with which a sample is irradiated in a sample observation according to a boosting method. The charged particle beam device includes: a charged particle source configured to generate the charged particle beam with which the sample is irradiated; an object lens configured to generate the magnetic field for focusing the charged particle beam; and a boosting electrode that is provided inside the object lens and to which a voltage for accelerating the charged particle beam is applied. The boosting electrode is formed of a magnetic material.

Abstract: A scanning electron microscope includes a spin detector configured to measure secondary electron spin polarization of secondary electrons emitted from the sample, and an analysis device configured to analyze secondary electron spin polarization data measured by the spin detector. The analysis device evaluates the strain in the sample by calculating a difference in the secondary electron spin polarization data of adjacent pixels.

Abstract: A charged particle beam device which prevents an appearance of a shading contrast due to azimuth discrimination and obtains a clear magnetic domain contrast image with a high resolution and a high throughput. The charged particle beam device includes an electron beam source; a sample stage; an objective lens configured to focus electron beams on a sample; a detector that is mounted on a charged particle beam source side with respect to the objective lens and separately detects secondary electrons emitted in azimuth angle ranges of two or more different azimuths for the same observation region; an image processing and image management device including an image processing unit configured to perform synthesis after performing shading correction and contrast adjustment on an image obtained by detecting a first emission azimuth and an image obtained by detecting a second emission azimuth; an image database; and an image display unit.

Abstract: A scanning electron microscope includes a spin detector configured to measure spin polarization of a secondary electron emitted from a sample, and an analysis device configured to analyze measurement data of the spin detector. The analysis device determines a width of a region where the secondary electron spin polarization locally changes in the measurement data. The analysis device further evaluates a strain in the sample based on the width of the region. With a configuration of the scanning electron microscope, it is possible to perform analysis of a strain in a magnetic material with high accuracy.

Abstract: A charged particle beam device includes: a charged particle source that emits a charged particle beam; a boosting electrode disposed between the charged particle source and a sample to form a path of the charged particle beam and to accelerate and decelerate the charged particle beam; a first pole piece that covers the boosting electrode; a second pole piece that covers the first pole piece; a first lens coil disposed outside the first pole piece and inside the second pole piece to form a first lens; a second lens coil disposed outside the second pole piece to form a second lens; and a control electrode formed between a distal end portion of the first pole piece and a distal end portion of the second pole piece to control an electric field formed between the sample and the distal end portion of the second pole piece.

Abstract: A scanning electron microscope includes a spin detector configured to measure spin polarization of a secondary electron emitted from a sample, and an analysis device configured to analyze measurement data of the spin detector. The analysis device determines a width of a region where the secondary electron spin polarization locally changes in the measurement data. The analysis device further evaluates a strain in the sample based on the width of the region. With a configuration of the scanning electron microscope, it is possible to perform analysis of a strain in a magnetic material with high accuracy.

Abstract: The present invention provides a charged particle beam apparatus capable of efficiently reducing the effect of a residual magnetic field when SEM observation is performed. The charged particle beam apparatus according to the present invention includes a first mode for passing a direct current to a second coil after turning off a first coil, and a second mode for passing an alternating current to the second coil after turning off the first coil.

Abstract: The present invention realizes a composite charged particle beam apparatus capable of suppressing a leakage magnetic field from a pole piece forming an objective lens of an SEM with a simple structure. The charged particle beam apparatus according to the present invention obtains an ion beam observation image while passing a current to a first coil constituting the objective lens, and performs an operation of reducing the image shift by passing a current to a second coil with a plurality of current values, and determines a current to be passed to the second coil based on a difference between the operations.

Abstract: A charged particle beam device includes: a charged particle source that emits a charged particle beam; a boosting electrode disposed between the charged particle source and a sample to form a path of the charged particle beam and to accelerate and decelerate the charged particle beam; a first pole piece that covers the boosting electrode; a second pole piece that covers the first pole piece; a first lens coil disposed outside the first pole piece and inside the second pole piece to form a first lens; a second lens coil disposed outside the second pole piece to form a second lens; and a control electrode formed between a distal end portion of the first pole piece and a distal end portion of the second pole piece to control an electric field formed between the sample and the distal end portion of the second pole piece.