Imaging the Unseen

Experience the power of our advanced cameras, delivering unmatched sensitivity, spatial resolution, and contrast. Our single-photon-counting cameras quickly uncover hidden details in various materials, from light composites to thick welded parts. The technology surpresses scattered radiation, capturing high quality images in record time. The capabilities of our photon-counting X-ray imaging unveil internal material structures and spot defects like porosity, fiber orientation, micro-cracks, and delaminations with unparalleled precision. Elevate your NDT with our industry-leading solutions, setting new standards in defect detection.

Do you need to determine the material composition of your sample? Minerals, alloys, polymers, electronics, batteries, or pigments? Our cameras are based on cutting-edge single X-ray photon counting sensors, and each detected photon is processed individually. This approach also allows measuring the wavelength of photons. It brings unprecedented image quality and new possibilities, such as material-sensitive X-ray imaging. Moreover, our detectors enable fast and compact X-Ray Diffraction (XRD) and Crystallography solutions. XRD sample analysis is performed up to an order of magnitude faster than conventional systems. Spectral sensitivity provides a unique ability to inspect the sample surface and its interior (Energy dispersive XRD).

Cancer research, bio-mechanics, and drug testing are just a few examples of X-ray imaging contributing to biological and medical research. New photon-counting detectors represent a severe advancement to these applications compared to previously used methods. The energy sensitivity of modern cameras opens better possibilities for identifying individual types of tissue and contrast agents. That has significant consequences in various industries, for example in cancer research, where the tumor tissue can be better distinguished from the healthy one.

ADVACAM offers cameras and solutions for multiple other applications, such as electron microscopy, crystallography, neutron imaging, localization of sources of ionizing radiation, charged particle tracking, and dosimetry for cancer therapy. In addition, many cameras are being used in basic research, such as at CERN's LHC accelerator, and for education on radiation and its properties in schools and universities.