Charged particle therapy has been largely driven and influenced by nuclear physics. The
increase in energy deposition density along the ion path in the body allows reducing the …

Radiographic imaging and tomography (RadIT), which started with Röntgen's seminal X-ray
work in 1895, now includes an increasing number of IT modalities. In addition to the original …

The highly transient nature of shock loading and pronounced microstructure effects on
dynamic materials response call for in situ, temporally and spatially resolved, x-ray-based …

Ultrafast radiographic imaging and tracking (U-RadIT) use state-of-the-art ionizing particle
and light sources to experimentally study sub-nanosecond transients or dynamic processes …

Applied nuclear physics is an essential part of the research activity at many particle
accelerators. New, large accelerator facilities are currently under construction in Europe …

Recent advances in image data proccesing through deep learning allow for new
optimization and performance-enhancement schemes for radiation detectors and imaging …

The Facility for Antiproton and Ion Research (FAIR) will employ the World's highest intensity
relativistic beams of heavy nuclei to uniquely create and investigate macroscopic (millimeter …

In the latest years, radiation therapy with ion beams has been rapidly spreading worldwide.
This is mainly due to the favourable interaction properties of ion beams with matter, offering …

The charged particle community is looking for techniques exploiting proton interactions
instead of X-ray absorption for creating images of human tissue. Due to multiple Coulomb …

An application of nuclear physics, a facility for using protons for flash radiography, has been
developed at the Los Alamos Neutron Science Center (LANSCE). Protons have proven far …