Developing an effective and robust system for deepening our understanding of the characteristics of the tissue, structure, mechanical properties and organization of bone at the level of the nanoscale, ...

X-ray diffraction methods lie at the foundation of materials science. Determination of the crystal structures of natural minerals and, later, of crystals grown in the laboratory led to our ...

X-ray diffraction (XRD) is a powerful non-destructive analytical technique used to evaluate crystalline materials and determine their structural properties. As one of the most widely used ...

Three-dimensional imaging is dramatically expanding our ability to examine biological specimens enabling a peek into internal structures. Recent advance in X-ray diffraction method has greatly ...

In order to determine the properties of a material, detailed knowledge of the structures it contains at the atomic level is required. This information can be obtained using conventional X-ray ...

X-ray diffraction (XRD) is an analytical method that probes the periodic arrangement of atoms in crystalline materials by measuring the angular distribution and intensity of X-rays scattered by the ...

Lab scale: Members of Ashley Bucsek’s group can now use three-dimensional X-ray diffraction to study polycrystalline materials on campus, whereas they would previously only have been able to do this ...

Particle size analysis is crucial to quality control and product development in a number of key industries including aerosols, construction, food and beverage, paint and coatings, and pharmaceuticals.

X ray spectrometry techniques are nowadays widely used in many analytical applications. The different interactions of x rays with matter have served to provide useful information for comprehensive ...

X-ray techniques have been used for decades by authorities to prevent crime and keep people safe. Perhaps their most well-known use is for the detection of dangerous and banned items or substances, ...