There is presented a screening system and a corresponding method for screening an item. The screening system includes a detection apparatus (100), a rotatable platform (310) to receive the item, and a mechanical arrangement (320, 330). The detection apparatus has an emitter portion to generate a primary beam of ionising radiation and a detector portion to detect an absorption signal and at least one of a diffraction signal and a scattering signal. The mechanical arrangement is adapted to translate the detection apparatus along a translation axis to scan the item with the primary beam. The screening system may be used for identifying restricted or illicit substances that may be present in some luggage or in mail.

There is presented a screening system and a corresponding method for screening an item. The screening system includes a detection apparatus (100), a rotatable platform (310) to receive the item, and a mechanical arrangement (320, 330). The detection apparatus has an emitter portion to generate a primary beam of ionising radiation and a detector portion to detect an absorption signal and at least one of a diffraction signal and a scattering signal. The mechanical arrangement is adapted to translate the detection apparatus along a translation axis to scan the item with the primary beam. The screening system may be used for identifying restricted or illicit substances that may be present in some luggage or in mail.

A system for inspecting an object includes a turntable on which the object may be placed. The turntable rotates the object about a first rotation axis. The system also includes an X-ray source to generate an X-ray beam in a plane to intersect with the object. The system also includes an X-ray detector that can detect at least a portion of the X-ray beam transmitted through the object during rotation and generate image data based on the detected X-ray beam. Also included is a controller that can: generate an image of the object based on the image data; determine, based on a suspect item identified in the image of the object, a second rotation axis at an angle from the first axis; cause a tilt of the turntable so that it is perpendicular to the second axis; and initiate a subsequent rotation of the object about the second axis.

Methods and systems for using dynamic data-driven detector tuning to investigate a sample with a charged particle microscopy system are disclosed herein. Methods and systems according to the present disclosure include acquiring sample data for a region of interest on the sample, and then determining one or more materials present in the region of interest. Once the materials are identified, a differentiation detector window is identified for the one or more materials, and the detector settings of a detector are adjusted such that the detector obtains information within the differentiation detector window. Thus, as the sample is subsequently scanned, the detector obtains an optimal range of information that is allows for efficient differentiation among the one or more materials.

A method for characterizing a sample combining an X-ray tomography characterization technique and a secondary ionization mass spectrometry characterization technique, includes: a step of providing a tip that includes first and second end surfaces, a first cylindrical region bearing the first end surface and a second region in contact with the first cylindrical region and becoming slimmer towards the second end surface; a step of machining the second region to obtain a sample holder including a flat surface, the flat surface forming an end surface of the sample holder, the area of the flat surface being less than the area of the first end surface; a step of placing the sample on the flat surface of the sample holder; a first step of characterization of the sample using an X-ray characterization technique; a second step of characterization of the sample using a secondary ionization mass spectrometry characterization technique.

A sample inspection system contains a source of electromagnetic radiation and an apparatus that includes a beam former, a collimator and an energy resolving detector. The beam former is adapted to receive electromagnetic radiation from the source to provide a polygonal shell beam formed of at least three walls of electromagnetic radiation. The collimator has a plurality of channels adapted to receive diffracted or scattered radiation at an angle. The energy resolving detector is arranged to detect radiation diffracted or scattered by a sample upon incidence of the polygonal shell beam onto the sample and transmitted by the collimator.

The invention relates to an X-ray CT method and in particular a registration-based dark-field tensor tomography method for testing a sample (60) by means of X-rays, with which method a sample (60) is consecutively scanned by means of X-rays in at least two fixed orientations differing from one another while rotating about a fixed rotation axis, in every orientation of the sample (60) on the basis of dark-field signals a plurality of scatter data sets is recorded, and the scatter data sets for different orientations are matched to one another by registration and combined into a common scatter data set reflecting a possible angular dependence of the scatter present due to the sample (60).

There is provided an X-ray utilized compound measuring apparatus in which troublesome tasks required to dispose a measurement object are reduced and the accuracy or the validity of measurements on multiple kinds of measurement can be improved. The X-ray utilized compound measuring apparatus comprises an X-ray generator 10 that outputs X-rays, a reflected-wave detector 12 that detects a reflected wave of the X-rays emitted from the X-ray generator 10 and reflected by a measurement object 21, a transmitted-wave detector 11 that detects a transmitted wave of the X-rays emitted from the X-ray generator 10 and passing through the measurement object 21, and a control unit that controls the X-ray generator 10 to output X-rays and performs computational processing for obtaining measurement values of a plurality of items on the measurement object 21 using a reflected-wave detection signal output from the reflected-wave detector 12 and representing the reflected wave and a transmitted-wave detection signal output from the transmitted-wave detector 11 and representing the transmitted wave and also performs computational processing for component analysis.

The present invention is intended to provide improved patterned X-ray emitting targets as well as X-ray sources that include patterned X-ray emitting targets as well as X-ray reflectance scatterometry (XRS) systems and also including X-ray photoelectron spectroscopy (XPS) systems and X-ray fluorescence (XRF) systems which employ such X-ray emitting targets.

Molecular structure of a crystal may be solved based on at least two diffraction tilt series acquired from a sample. The two diffraction tilt series include multiple diffraction patterns of at least one crystal of the sample acquired at different electron doses. In some examples, the two diffraction tilt series are acquired at different magnifications.