An inspection apparatus for inspecting an inspection target surface arranged on an inspection plane, includes an X-ray generation tube having a target including an X-ray generation portion that generates X-rays by irradiation with an electron beam, and configured to emit X-rays to the inspection plane, and an X-ray detector configured to detect X-rays emitted from a foreign substance existing on the inspection target surface irradiated with the X-rays from the X-ray generation portion and totally reflected by the inspection target surface. The X-ray detector includes a long X-ray receiver.

A risk of breakage of a sample holder can be reduced and a biochemical sample or a liquid sample can be observed easily and with a high observation throughput. A sample holder 101 holding a sample includes: a sample chamber including a first insulating thin film 110 and a second insulating thin film 111 that sandwich and hold the sample 200 in a liquid or gel form and face each other, a vacuum partition wall inside which the sample chamber holding the sample is fixed in a state in which the thin film is exposed to a surrounding atmosphere, and whose internal space is kept at a degree of vacuum at least lower than that of the sample room at the time of observation of the sample, a detection electrode 820 disposed to face the second insulating thin film in a state in which the sample chamber is fixed to the vacuum partition wall, and a signal detection unit 50 connected to the detection electrode. Before the surrounding atmosphere of the sample holder is evacuated from an atmospheric pressure to a vacuum, the charged particle beam device receives a detection signal from the signal detection unit via a connector and detects an abnormality of the sample chamber based on the detection signal.

Described herein is a high-energy x-ray imaging system including a stationary gantry, a conveyor assembly configured to convey an object to be imaged through the gantry, a plurality of linear accelerators, a detector array, and a control system. The linear accelerators are arranged in an array within the gantry and are configured to generate high-energy x-ray fan beams to be transmitted through the object. The detector array is positioned opposite the linear accelerators and is configured to collect the high-energy x-ray fan beams transmitted through the object. The control system is configured to energize the linear accelerators according to a predetermined control sequence to generate the high-energy x-ray fan beams, and construct a 3-D image of the object based on data received from the detector array and representative of the high-energy x-ray fan beams transmitted through the object.

An x-ray fluorescence system and method of fabrication are provided which include a titanium x-ray source, a focusing, doubly-curved lithium fluoride (LiF) crystal optic, and a detector. The titanium x-ray source includes a titanium target on which electrons impinge to generate a diverging x-ray beam with a titanium-based characteristic energy, and the focusing, doubly-curved LiF crystal optic monochromates and focuses the diverging x-ray beam from the titanium x-ray source to provide a monochromated and focused x-ray excitation beam directed to impinge on a sample. The crystal optic and the titanium x-ray source operate at a Bragg angle which facilitates polarization within the x-ray fluorescence system. The detector receives fluorescence from the sample induced by the x-ray excitation beam impinging thereon, with the fluorescence is indicative of a concentration of at least one element in the sample.

The present invention relates to a battery module comprising a particulate metal-dispersed thermal conductive resin, and a method and a system for inspecting same. The present invention can effectively inspect the degree of dispersion in the resin in a nondestructive manner and can detect a defect.

Disclosed example radiographic source exposure devices include: a radiographic source capsule having a radionuclide; a radiographic shield; a channel within the radiographic shield, the channel having a first end and a second end; and a replaceable tube configured to guide a radiographic source capsule between a stored position and an exposed position in which at least a portion of the radiographic source capsule is exposed to an exterior of the radiographic shield.

An X-ray generation device includes an electron gun emitting an electron beam, an X-ray generation target including a plurality of target parts generating X-rays in response to incidence of the electron beam from the electron gun, and an irradiation area switching unit switching an area of the X-ray generation target irradiated with the electron beam between a first irradiation area and a second irradiation area. The number of target parts included in the first irradiation area is larger than the number of target parts included in the second irradiation area. An area of the target parts included in the first irradiation area is larger than an area of the target parts included in the second irradiation area.

In a Schottky emitter or a thermal field emitter using a hexaboride single crystal, side emission from portions other than an electron emission portion is reduced. An electron source according to the invention includes: a protrusion (40) configured to emit an electron when an electric field is generated; a shank (41) that supports the protrusion (40) and has a diameter decreasing toward the protrusion (40); and a body (42) that supports the shank (41), in which the protrusion (40), the shank (41), and the body (42) are each made of a hexaboride single crystal, and a part including the shank (41) and the body (42) excluding the protrusion (40) is covered with a material having a work function higher than that of the hexaboride single crystal.

Disclosed example radiographic source exposure devices include: a radiographic source capsule having a radionuclide; a radiographic shield; a channel within the radiographic shield, the channel having a first end and a second end; and a replaceable tube configured to guide a radiographic source capsule between a stored position and an exposed position in which at least a portion of the radiographic source capsule is exposed to an exterior of the radiographic shield.

The present invention relates to an X-ray inspection apparatus and method. The X-ray inspection apparatus according to one embodiment includes a transfer unit configured to transfer a subject in a first direction, a plurality of X-ray sources arranged to be spaced apart from each other in a second direction intersecting the first direction and configured to radiate X-rays toward the subject, an X-ray control unit configured to control an arrangement of the plurality of X-ray sources, a detection unit positioned below the transfer unit and configured to detect an X-ray transmission image passing of the X-rays through the subject, and an image processing unit configured to generate an X-ray image based on the X-ray transmission image detected by the detection unit.