Higher intensity x-ray beams don’t always give stronger diffraction patterns Using ultrahigh-intensity x-ray beams can cause the intensity of diffraction patterns from samples to drop Figure 1: An ...

The highest intensity diffraction plane (222) was chosen as the subject of the time-resolved diffraction experiments and changes in both the location and intensity of the x-ray diffraction peaks ...

X-ray crystallography, like mass spectroscopy and nuclear spectroscopy, is an extremely useful material characterization technique that is unfortunately hard for amateurs to perform. The physical ...

Single-crystal X-ray diffraction systems are used for routine analytical chemistry and challenging small molecule and protein diffraction studies. The new facility is located only a few kilometers ...

X-ray diffraction is a powerful tool for characterizing materials and distinguishing between different crystalline phases. However, for nanocrystalline materials with prominent peaks, decimal ...

Potential applications of the new technique, known as “dark-field hyperspectral X-ray imaging”, include identification of stress build-up inside engineered structures, security scanning of elicit ...

2D-XRD, or two-dimensional X-ray diffraction, is a powerful analytical technique used to study the atomic and molecular structure of crystalline materials at the nanoscale. It provides detailed ...

Figure 2: Comparison of room temperature X-ray powder-diffraction (XRPD) pattern (red) and calculated XRPD pattern from the single crystal structure at 120 K (blue) for the 1:1 cocrystal of p-coumaric ...

Using ultrahigh-intensity x-ray beams can cause the intensity of diffraction patterns from samples to drop.