A radiation detector includes a substrate including a first electrode portion, a radiation absorption layer disposed on one side with respect to the substrate and configured of a plurality of perovskite crystals, and a second electrode portion disposed on the one side with respect to the radiation absorption layer and being opposite to the first electrode portion with the radiation absorption layer interposed therebetween. Each of the plurality of perovskite crystals is formed to extend with a first direction in which the first electrode portion and the second electrode portion are opposite to each other as a longitudinal direction in a region between the first electrode portion and the second electrode portion in the radiation absorption layer.

The present disclosure relates to fabrication and use of a phase-contrast imaging detector that includes sub-pixel resolution electrodes or photodiodes spaced to correspond to a phase-contrast interference pattern. A system using such a detector may employ fewer gratings than are typically used in a phase-contrast imaging system, with certain functionality typically provided by a detector-side analyzer grating being performed by sub-pixel resolution structures (e.g., electrodes or photodiodes) of the detector. Measurements acquired using the detector may be used to determine offset, amplitude, and phase of a phase-contrast interference pattern without multiple acquisitions at different phase steps.

An X-ray inspection device of the present invention includes a sample placement unit 11 for placing a sample as an inspection target therein, a sample placement unit positioning mechanism 30 for moving the sample placement unit 11, a goniometer 20 including first and second rotation members 22, 23 that rotate independently of each other, an X-ray irradiation unit 40 installed on the first rotation member 22, and a two-dimensional X-ray detector 50 installed on the second rotation member 23. The sample placement unit positioning mechanism 30 includes a χ rotation mechanism 35 for rotating the sample placement unit 11 and a ϕ-axis about a χ-axis that is orthogonal to a θs-axis and a θd-axis at a measurement point P and extends horizontally.

The invention relates to a method for characterizing a sample, by estimating a plurality of characteristic thicknesses, each being associated with a calibration material, comprising the following steps:

acquiring an energy spectrum (S.sup.ech) transmitted through this sample, located in an X and/or gamma spectral band, naled spectrum transmitted through the sample;

for each spectrum of a plurality of calibration spectra (S.sup.base(L.sub.k; L.sub.l)), calculating a likelihood from said calibration spectrum (S.sup.base(L.sub.k; L.sub.l)), and from the spectrum transmitted through the sample (S.sup.ech), each calibration spectrum (S.sup.base(L.sub.k; L.sub.l)) corresponding to the energy spectrum transmitted through a stack of gauge blocks, each formed of a known thickness of a calibration material;

estimating the characteristic thicknesses (L.sub.1, L.sub.2) associated with the sample according to the criterion of maximum likelihood.

Devices and methods for characterization of analyte mixtures are provided. Some methods described herein include performing enrichment steps on a device before expelling enriched analyte fractions from the device for subsequent analysis. Also included are devices for performing these enrichment steps.

Disclosed herein is a method comprising: determining doses of radiation received by a first set of pixels of a radiation detector; determining that the doses satisfy a criterion; adjusting exposure of the radiation detector to the radiation in response to the doses satisfying the criterion; and forming an image based on radiation received by a second set of pixels of the radiation detector.

A flexible digital radiographic detector assembly uses a conformable bag having granular media therein to enclose the detector and to help fit the detector onto a curved object. The conformable bag is evacuated to hold the detector against the object to be imaged. An image of the object is acquired by aiming x-rays through the object toward the detector.

An X-ray scattering apparatus has a sample holder for aligning and orienting a sample to be analyzed by X-ray scattering, an X-ray beam delivery system arranged upstream of the sample holder for generating and directing a direct X-ray beam along a propagation direction towards the sample holder, a proximal X-ray detector arranged downstream of the sample holder as to let the direct X-ray beam pass and detect X rays scattered from the sample, and a distal X-ray detector arranged downstream of the sample holder and movable along the propagation direction (X) of the direct X-ray beam in which the proximal X-ray detector is also movable essentially along the propagation direction of the direct X-ray beam.

A method for characterizing a sample, by estimating a plurality of characteristic thicknesses, each being associated with a calibration material, including acquiring an energy spectrum (S.sup.ech) transmitted through this sample, located in an X and/or gamma spectral band; for each spectrum of a plurality of calibration spectra (s.sup.base(L.sub.k; L.sub.t)) calculating a likelihood from said calibration spectrum (S.sup.base(L.sub.k; L.sub.t)), and from the spectrum transmitted through the sample (S.sup.ech), each calibration spectrum (S.sup.base(L.sub.k; L.sub.t)) corresponding to the energy spectrum transmitted through a stack of gauge blocks, each formed of a known thickness of a calibration material; estimating the characteristic thicknesses (L.sub.1, L.sub.2) associated with the sample according to the criterion of maximum likelihood.

An X-ray inspection device of the present invention includes a sample placement unit 11 for placing a sample as an inspection target therein, a sample placement unit positioning mechanism 30 for moving the sample placement unit 11, a goniometer 20 including first and second rotation members 22, 23 that rotate independently of each other, an X-ray irradiation unit 40 installed on the first rotation member 22, and a two-dimensional X-ray detector 50 installed on the second rotation member 23. The sample placement unit positioning mechanism 30 includes a rotation mechanism 35 for rotating the sample placement unit 11 and a -axis about a -axis that is orthogonal to a s-axis and a d-axis at a measurement point P and extends horizontally.