Celebrating 125 Years of the Discovery of X-rays

EDXRF instruments, thanks to their versatility, are used in a variety of applications for rapid elemental screening of materials both in the laboratories and in the field. Since the analysis is, in most cases, non-destructive, they are used in laboratories dealing with forensic science, authentication of gemstones, environmental samples such as air filters, water or soils, polymers, chemicals, additives and food.

X-ray Diffraction is a structural analysis technique used in both industrial and research labs for mineralogical analysis (phases, compounds) and crystallography. Thermo Fisher Scientific offers a range of XRF and XRD instruments for these laboratories which can be used as stand-alone techniques or completely integrated with other techniques in a fully automated workflow.

X-ray Microanalysis is an analytical technique used in electron microscopes for elemental or chemical analysis characterization of samples such as metals, geological materials, and semiconductor materials. Techniques include energy-dispersive spectroscopy (EDS) and wavelength-dispersive spectroscopy (WDS). Using spectral imaging data as its foundation along with an array of processing algorithms that assure the most precise data possible, Thermo Scientific Pathfinder Software changes the way microscopists use EDS and WDS  by going straight to the classification of the chemical phases in your sample. This greatly reduces the time needed to understand the chemical composition of a sample. This is now combined with Thermo Scientific ColorSEM Technology, which turns scanning electron microscopy into a color imaging technique. Elemental information is shown as colors in the live image for direct feedback on the composition. This provides the quickest and most intuitive access to elemental information at the microscale.

XRF (X-ray fluorescence) is a non-destructive analytical technique used to determine the elemental composition of materials. XRF analyzers determine the chemistry of a sample by measuring the fluorescent (or secondary) X-ray emitted from a sample when it is excited by a primary X-ray source. Each of the elements present in a sample produces a set of characteristic fluorescent X-rays ("a fingerprint") that is unique for that specific element, which is why XRF spectroscopy is an excellent technology for qualitative and quantitative analysis of material composition.

› Read more about XRF technology.

XPS isalso known as electron spectroscopy for chemical analysis (ESCA), is a technique for analyzing the surface chemistry of a material. XPS can measure the elemental composition, empirical formula, chemical state and electronic state of the elements within a material. XPS spectra are obtained by irradiating a solid surface with a beam of X-rays while simultaneously measuring the kinetic energy of electrons that are emitted from the top 1-10 nm of the material being analyzed.

Surface analysis contributes to the understanding for each of these areas: semiconductor/microelectronics, ultra-thin films, coatings, catalysis, welding, glass, corrosion, oxidation, failure, adhesives, motor/avionics, chemical and metal industries, and others.

Today’s microCT is a direct result of the first X-ray image taken 125 years ago. The first X-rays are credited to Wilhelm Röntgen (1845–1923) who took an X-ray image of the left hand of his wife Anna Bertha Ludwig, wearing her wedding ring. If you search the web for the image, you’ll see a blurry skeletal hand with a dark ring around the left ring finger. This first image taken on a glass plate is very comparable to the 2D projection images taken by the digital detectors of today. We have come a far way in 125 years, but the basics are still the same. The 2D images are reconstructed in a virtual 3D volume by advanced algorithms.

Understanding the elemental composition of your materials at multiple touchpoints in the workflow process can help you adapt to new challenges unique to your market sector. We offer the products, services and technologies to help you understand your materials, regardless of the application. See our listing of resources for XRF in these areas:

• Metals/Alloys
• Cement
• Geology/Mining/Minerals
• Petroleum
• Polymers
• Glass/Ceramics
• Energy
• Environmental

Understanding the structure of your materials can help you adapt to new challenges unique to your market sector. We offer the products, services and technologies to help you understand your materials, regardless of the application. See our listing of resources for XRD in these areas:

• Geology/Mining/Minerals
• Polymers
• Pharmaceuticals
• Glass/Ceramics
• Energy

Online slurry analysis systems provide accurate, real-time elemental analysis for process control of slurry streams for both light and heavy elements in minerals processing operations. Accurate, high-availability elemental analysis helps enable improvements in product quality, recovery and lower production costs. For any given metallurgical plant there are several key factors which need to be addressed in selecting the most suitable online elemental analysis system configuration for process control. Here are some frequently asked questions and answers about process control for online slurry analysis in metallurgical plants.

Detecting physical contaminants in food, such as metal, glass, stone, plastic, and bone is like trying to find a needle in a haystack, especially when the contaminant may be as small as 1 mm in diameter. X-ray detection systems provide the highest sensitivity so you can find virtually any foreign object in your packaged food products. X-ray inspection systems are based on the density of the product and the contaminant. As an X-ray penetrates a food product, it loses some of its energy. A dense area, such as a contaminant, will reduce the energy even further. As the X-ray exits the product, it reaches a sensor. The sensor then converts the energy signal into an image of the interior of the food product. Foreign matter appears as a darker shade of grey and helps identify foreign contaminants.