The Boeing Company, Huntsville, Alabama, is being awarded a more than $23 million task order for the critical design of a 100-kW class Free Electron Laser (FEL) device to demonstrate scaleability of ...

New research by scientists from the U.S. Department of Energy's Lawrence Berkeley National Laboratory (Berkeley Lab), in collaboration with scientists from TAU Systems Inc., has brought the promise of ...

Representation of domain walls within a ferromagnetic layered material. New research shows that when these materials are hit with a free electron laser, magnetic domain walls move much faster than ...

Construction plan of the Plasma-X-FEL. Credit: University of Strathclyde / Science Communication Lab Ice-cold electron beams simulated in research at the University of Strathclyde could pave the way ...

Picture of the experimental hall showing the target interaction chamber on the left, the collection vacuum tube and the detector on the right side. Credit: Gianluca Gregori. Researchers at the ...

Free-electron lasers (FELs) represent a transformative technology in the generation of coherent X-ray pulses that are both remarkably bright and ultrashort in duration. By utilising relativistic ...

Agostino "Ago" Marinelli first met pioneering accelerator physicist Claudio Pellegrini as an undergraduate student at the University of Rome. It was 2007, a couple of years before the Linac Coherent ...

Extremely intense light pulses generated by free-electron lasers (FELs) are versatile tools in research. Particularly in the X-ray range, they can be deployed to analyze the details of atomic ...

The Wakefield Acceleration and Radiation Generation (WARG) research group is led by Prof. Mike Litos of the CU Physics Department and the Center for Integrated Plasma Studies (CIPS). Our primary area ...

The USA has only two accelerators that can produce 10 billion electron-volt particle beams, and they're each about 1.9 miles (3 km) long. "We can now reach those energies in 10 cm (4 inches)," said ...

A team of physicists from the University of Ottawa have developed a new theoretical model that shines new light on how scientists understand the way lasers interact with dense matter, such as solids ...