Linear accelerators have become an indispensable component in the advancement of particle therapy, offering precise control over the delivery of ionising radiation for cancer treatment. The field ...

Particle accelerators produce and accelerate beams of charged particles, such as electrons, protons and ions, of atomic and sub-atomic size. They are used not only in fundamental research for an ...

Innovative machine learning techniques are rapidly transforming particle accelerator physics by integrating advanced data analytics with established accelerator models. This integration has led to ...

A new pocket-sized particle accelerator has proven capable of projecting ultra-short electron beams with laser light at more than 99.99% of the speed of light. Researchers, led by Lancaster and ...

In 2012, particle accelerators hit the headlines when researchers at CERN announced the discovery of the Higgs boson. This breakthrough discovery resulted from decades of research and experimentation ...

What’s the difference between a synchrotron and a cyclotron, anyway? Research in high-energy physics takes many forms. But most experiments in the field rely on accelerators that create and speed up ...

Critical components of all particle accelerators, beam diagnostics are responsible for quantifying the parameters of particle beams. Beam diagnostics are capable of providing extremely accurate ...

Whenever SLAC National Accelerator Laboratory's linear accelerator is on, packs of around a billion electrons each travel together at nearly the speed of light through metal piping. These electron ...

The Large Hadron Collider is known for discovering the Higgs boson, but the technologies used in accelerating and detecting new particles also have uses outside of high-energy physics. Carsten Welsch ...

Alex Bogacz, a senior scientist at the U.S. Department of Energy's Thomas Jefferson National Accelerator Facility since 1997, has spent his career in accelerator physics solving problems. From ...