Articles tagged with Electroweak Interaction
Researchers at TUM have discovered that deuterons and antideuterons are formed through the decay of highly energetic particle states, releasing protons and neutrons necessary for their formation. This finding improves models of particle formation and could provide clues about dark matter.
A team of researchers from Chiba University successfully measured the interaction rates of high-energy electron and muon neutrinos using the FASERν detector at the Large Hadron Collider. The study marked the first direct observation of these interactions at a particle collider, providing new insights into particle physics.
Researchers at Hokkaido University have discovered that elusive neutrinos can interact with photons in ways not previously detected under extreme conditions. This finding has implications for understanding quantum mechanical interactions of fundamental particles and may help reveal details of the solar corona heating puzzle.
A new experiment measures the neutron skin in a calcium nucleus, shedding light on proton-neutron interactions. The results will be presented at the 2021 Fall Meeting of the APS Division of Nuclear Physics.
The article proposes a connection between SLq(2) and the standard model, where preons are creation operators for fundamental particles. This extension describes a finer level of structure than the standard model, with open problems including gravitational binding and renormalization.