The Department of Energy's Heavy Ion Fusion Science Virtual National Laboratory (HIFS-VNL), whose member institutions include LLNL, ... New accelerator to examine heavy-ion-beam approach.

A research team has developed a large-area suspended graphene and irradiated the thinnest graphene target with an ultra-intense laser to realize high-energy ion acceleration. Their findings will ...

Laser-driven ion acceleration may one day provide a compact, cost-effective alternative – but current techniques cannot match the energy and quality of beams created by conventional accelerators.

Enhanced ion acceleration from transparency-driven foils demonstrated at two ultraintense laser facilities. Light Publishing Center, Changchun Institute of Optics, Fine Mechanics And Physics, CAS ...

More information: Hui-bo Tang et al, Laboratory observation of ion drift acceleration via reflection off laser-produced magnetized collisionless shocks, Science Advances (2025). DOI: 10.1126 ...

A research team led by Osaka University developed a large-area suspended graphene and irradiated the thinnest graphene target with an ultra-intense laser to realize high-energy ion acceleration.

Metals travel forward in time at the Ion Accelerator Laboratory, a facility within Texas A&M University's Department of Nuclear Engineering and researchers within the department's Ion Beam ...

So it has been necessary to use plasma mirrors, which remove the noise components, to achieve efficient ion acceleration with an intense laser. ‘Large-area suspended graphene’ Thus, the researchers ...

Laser-driven ion acceleration has many applications in medicine, plasma diagnostics and engineering as well as basic science. To bring these capabilities to facilities without the super-intense lasers ...