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).

Mask-modulated spectra are incident to a sensor and are summed during a frame time. After the frame time, a compressed spectrum is read out based on the sum and decompressed to obtain spectra for some or all specimen locations. The mask-modulated spectrum that are summed are associated with different modulations produced by a common mask.

An electron beam sterilization unit for processing food packaging material, the unit having a frame; at least one electron beam emitter fitted to the frame, along the path of the material for processing, and having a flange for connection to the frame; and a locking device, which is fitted to the frame, and has thrust devices for exerting a lock force on the flange in a given first direction, and for locking the emitter, with respect to the frame, in a given work position, and actuating devices for activating the thrust devices and which are defined by toggle devices.

The purpose of the present invention is to provide a pattern measurement device for quantitatively evaluating a pattern formed using a directed self-assembly (DSA) method with high accuracy. The present invention is a pattern measurement device for measuring distances between patterns formed in a sample, wherein the centroids of a plurality of patterns included in an image are determined; the inter-centroid distances, and the like, of the plurality of centroids are determined; and on the basis of the inter-centroid distances, and the like, of the plurality of centroids, a pattern meeting a specific condition is distinguished from patterns different from the pattern meeting the specific condition or information is calculated about the number of the patterns meeting the specific condition, the size of an area including the patterns meeting the specific condition, and the number of imaginary lines between the patterns meeting the specific condition.

A hollow metal article can be fabricated by casting a molten metal alloy around a core, solidifying the molten metal alloy to form a metal article, and chemically removing the core from the metal article to form a hollow cavity in the metal article. The core includes a ceramic core body and an x-ray radiopaque coating disposed on the ceramic core body. A method for testing the hollow metal article includes submitting the hollow metal article to x-ray imaging and determining based upon the x-ray imaging whether any of the x-ray radiopaque coating of the core remains in the hollow metal article.

A hollow metal article can be fabricated by casting a molten metal alloy around a core, solidifying the molten metal alloy to form a metal article, and chemically removing the core from the metal article to form a hollow cavity in the metal article. The core includes a ceramic core body and an x-ray radiopaque coating disposed on the ceramic core body. A method for testing the hollow metal article includes submitting the hollow metal article to x-ray imaging and determining based upon the x-ray imaging whether any of the x-ray radiopaque coating of the core remains in the hollow metal article.

The invention relates to a photon detector (10), in particular an x-ray detector, in the form of a measurement finger, which extends along a detector axis (23) and has a detector head (11) at a first end of the measurement finger, wherein the detector head (11) comprises a plurality of at least two detector modules (22), each comprising a sensor chip (12) sensitive to photon radiation (14), in particular x-radiation, said sensor chip having an exposed end face (13) and a face facing away from the end face (13), wherein the detector modules (22) are arranged around the detector axis (23) in a plane (24) extending orthogonally to the detector axis (23).

A dosimeter includes a substrate and a plurality of nanowire pairs located on the substrate. The plurality of nanowire pairs simulate a plurality of human chromosome pairs. A method of determining an effect of delivering ionizing radiation with a dosimeter having a substrate and a plurality of nanowire pairs located on the substrate, wherein the plurality of nanowire pairs simulate a plurality of human chromosome pairs is provided. The method includes the steps of delivering ionizing radiation to the plurality of nanowire pairs; acquiring information relating to the ionizing radiation; and determining, from the information, the effect of the delivered radiation on the plurality of nanowire pairs.

A dosimeter includes a substrate and a plurality of nanowire pairs located on the substrate. The plurality of nanowire pairs simulate a plurality of human chromosome pairs. A method of determining an effect of delivering ionizing radiation with a dosimeter having a substrate and a plurality of nanowire pairs located on the substrate, wherein the plurality of nanowire pairs simulate a plurality of human chromosome pairs is provided. The method includes the steps of delivering ionizing radiation to the plurality of nanowire pairs; acquiring information relating to the ionizing radiation; and determining, from the information, the effect of the delivered radiation on the plurality of nanowire pairs.

A modular X-ray computed tomography (XCT) system having a higher degree of modularity provides experimental versatility and in situ capabilities. The modular XCT system includes interchangeable X-ray sources and detectors that allow for the XCT system to be readily adapted to different imaging tasks, such as those that may require different trade-offs between spatial resolution, exposure time, power, and other scanning parameters.