Physicists at CERN’s Large Hadron Collider (LHC) have made a groundbreaking discovery that could reshape our understanding of ...

Instead of creating a new sensor system from scratch, the researchers repurposed sixty 64-megapixel mobile camera sensors to ...

During the Moriond Conference in Italy, the LHCb collaboration at CERN announced that a new milestone had been reached in our understanding of the subtle yet profound differences between matter and ...

It's a crucial explanation for why matter was able to dominate over antimatter in the early universe — without it, the universe would be an empty void. Despite being a key reason why we're here ...

Physicists from CERN working on Large Hadron Collider, came close to answering why there was more matter in the early Universe than antimatter. It is noted that the discovery made at the collider ...

Intriguing signs from CERN hint at a never-before-seen form of matter – one that could be the tiniest particle cluster ever detected. Top quarks, typically too short-lived to pair up, may have briefly ...

There’s a newfound mismatch between matter and antimatter. And that could bring physicists one step closer to understanding how everything in the universe came to be. For the most part ...

(via PBS Space Time) At one-one-thousandth of a second after the Big Bang, the great annihilation event should have wiped out all matter, leaving a universe of only radiation. Why still don't know why ...

Interestingly, such gamma rays are produced when an electron and its antimatter counterpart (all ... elusive ingredients in the universe: dark matter. In particular, we propose that a new form ...

The purpose of this note is to direct attention to what may be a close analogue to the evolution of ‘local pockets’ of matter and antimatter in the Universe.

(via Fermilab) Scientists study antimatter, investigating the ways in which it acts like ordinary matter and the ways in which it differs. Antimatter is the opposite of ordinary matter and, when ...