It took over 80,000 baryon decays for us to observe, for the first time, a matter-antimatter asymmetry in this category of particles." View of the LHCb experiment in its underground cavern (image ...

The discovery of the new antihypernucleus could help scientists better understand the state of the universe just a millionth ...

Although our universe is mostly normal matter, antimatter isn’t so hard to create — supernovae, black holes, and even bananas ...

LHCb’s discovery of proton-like particles behaving differently than their antimatter counterparts brings scientists one step ...

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

It took over 80 000 baryon decays for us to see matter–antimatter asymmetry with this class of particles for the first time.” "This is a landmark discovery in these studies, as it is the first time a ...

"It took over 80,000 baryon decays for us to see matter–antimatter asymmetry with this class of particles for the first time." According to the standard model of cosmology, in the aftermath of the Big ...

Asymmetric interactions between molecules may serve as a stabilizing factor for biological systems. A new model by ...

It took over 80,000 baryon decays for us to observe, for the first time, a matter-antimatter asymmetry in this category of particles." View of the LHCb experiment in its underground cavern (image: ...

This is only the third hypernuclei ever discovered, and it could help scientists better understand things like the matter-antimatter asymmetry and the strange physics of neutron stars. One of the ...