Researchers at the Large Hadron Collider found evidence of an unprecedentedly heavy and exotic form of antimatter in the ...

RIKEN physicists have devised a theoretical method to probe elusive Majorana fermions in topological superconductors by ...

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

As if atoms weren’t already mind-blowingly small, never mind subatomic particles, CERN researchers in the CMS Collaboration were sifting through data from the Large Hadron Collider (LHC) and ...

As the world gears up for more powerful particle colliders, new 4D quantum sensors tested at Fermilab promise sharper ...

"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 ...

Quasicrystals, exotic states of matter characterized by an ordered structure with non-repeating spatial patterns, have been ...

The standard cosmological model assumes that after the Big Bang, the Universe was a hot plasma-filled space of matter and antimatter particles. They emerged and destroyed each other in the process of ...

To learn more about the nature of matter, energy, space, and time, physicists smash high-energy particles together in large ...

In their search for more flavors of Higgs bosons, a team of researchers at CERN stumbled across what could be evidence of the smallest matter-antimatter ... never mind subatomic particles, CERN ...