IFLScience traveled to CERN to get an exclusive insight into the crucial theory of particle physics, its limitations, and ...

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

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

Despite being a key reason why we're here in the first place, the amount of CP violation predicted by the Standard Model of particle physics is far too small to explain the abundance of matter in ...

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

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 ...

Meanwhile, according to the Standard Model of particle physics, the number of CP-invariance violations is too small to explain such an amount of standard matter in the Universe. Prior to this ...

Measuring the probability, or cross section, of tt-bar production is both an important test of the Standard Model of particle physics and a powerful way to search for the existence of new ...

The revision takes scientists one more step toward a discovery that could alter or even upend the Standard Model of particle physics. Our universe is awash with phantom specks of matter.

This discovery provides new clues to explain the arrangement of elementary particles composing matter in the Standard Model of particle physics and to understand why, it seems, matter prevailed over ...