Physicists at the European Organization for Nuclear Research (CERN) use AI to search for subatomic particle evidence. CERN ...

In 2012, the ATLAS and CMS experiments confirmed the discovery of the Higgs Boson. Predictions and limitations of the Standard Model Apart from the Higgs boson, the model predicted the force ...

The majority of our evidence for dark matter’s existence comes from observing visible (or baryonic) matter that does not ...

The complete Standard Model took a long time to build. Physicist J.J. Thomson discovered the electron in 1897, and scientists at the Large Hadron Collider found the final piece of the puzzle, the ...

More than a decade after its groundbreaking discovery, the Higgs boson continues to captivate the scientific community. This elusive particle, famously nicknamed the “God particle,” plays ... Continue ...

a magnetic relative of the mass-defining Higgs Boson particle, the team reports in the online edition of the journal Nature. The detection a decade ago of the long-sought Higgs Boson became central to ...

Excessive dark matter mass may disrupt the Higgs boson Heavier dark matter challenges Standard Model physics Lighter particles like axions gain research attention ...

Join six leading experts to find out everything we know about the subatomic universe. Take a deep dive into the building blocks of the universe, from the atom to the standard model, and learn how ...

If a fermion, such as a quark or lepton produces a boson, which is then taken in by another fermion, then a force exists between the two fermions. The Higgs boson is responsible for the mass of ...

The underlying theoretical construct in particle physics is called the Standard Model and it contains 6 quarks, 6 leptons, 4 gauge bosons, and one scalar boson (the Higgs boson), which interact ...

Dark matter can't be too heavy or it might break our best model of the universe ... regular particles through exchanges involving the Higgs boson — a fundamental particle that interacts with ...