What is Scanning X-Ray Fluorescence (XRF) Microscopy? Scanning X-Ray Fluorescence (XRF) Microscopy is a powerful analytical technique that enables the visualization and quantification of the elemental ...

X-ray fluorescence imaging and computed tomography represent a convergent approach that combines elemental sensitivity with high-resolution anatomical imaging. By utilising characteristic secondary ...

Flow-assisted corrosion, also termed flow-accelerated corrosion or FAC, has long been a common problem for nuclear and fossil fuel power plants in which steel piping and its components are degraded ...

In this interview, Michael Hull talks about using portable X-ray fluorescence for detecting and quantifying mercury contamination in the field. What are the health and environmental risks associated ...

How can the component elements of an unknown material, such as a meteorite, be determined? X-ray fluorescence analysis can be used to identify an abundance of elements, by irradiating samples with ...

Elemental analysis plays a crucial role in the pharmaceutical industry, allowing scientists to understand a material or compound’s elemental composition. It also provides key information on any ...

The copper target was operated at voltages of 11 kV, 12 kV, 13 kV, and 14 kV for the electron source, and a 50 kV configuration using a molybdenum target was used as a representative example for the ...

X-ray fluorescence (XRF) offers element-selective information that can be used for the qualitative and quantitative analysis of various sample types. In this article, we explore how XRF spectroscopy ...

A research team has developed a new method to produce X-ray images in color. In the past, the only way to determine the chemical composition of a sample and the position of its components using X-ray ...

Editor’s Note: This Q&A is one of a series of articles exploring the research that University of Delaware students have been pursuing. Follow our “Frontiers of Discovery” series as UDaily highlights ...

Researchers propose building fluorescence directly into microplastic polymer structures, enabling stable real-time imaging of how particles move, accumulate, and degrade in biological systems.