Why matter dominates over antimatter in our universe has long been a major cosmic mystery to physicists. A new finding by the ...

Matter and antimatter should have completely wiped each other out eons ago, leaving the Universe a very empty place.

This could revolutionize antimatter experiments with real-time, ultra-high precision imaging. Using a beam of antihydrogen and a groundbreaking detector made from modified mobile phone camera sensors, ...

"I congratulate the LHCb collaboration on this brilliant result," says Joachim Mnich, CERN's Director for Research and Computing. "It once again highlights the scientific potential of the LHC and its ...

The AEgIS collaboration, led by a team from the Technical University of Munich, has repurposed smartphone camera sensors to create a detector capable of imaging antiproton annihilations in real time ...

The Antiproton Decelerator established at CERN in the late 1990s began providing slower moving, lower-energy antiprotons for antimatter experiments. In these experiments, electric and magnetic fields ...

Matter and antimatter should have completely wiped each other out eons ago, leaving the Universe a very empty place. Obviously that didn't happen. Experiments at the Large Hadron Collider (LHC ...

Neutrinos, elusive fundamental particles, can act as a window into the center of a nuclear reactor, the interior of the Earth ...

Why matter dominates over antimatter in our universe has long been a major cosmic mystery to physicists. A new finding by the world's largest particle collider has revealed a clue.

Physicists from CERN working on Large Hadron Collider, came close to answering why there was more matter in the early ...