After years of extremely precise experiments, a group of researchers at CERN finally succeeded in creating and carefully capturing a sample of antihydrogen (the antimatter version of hydrogen) in September of this year. The sample was held in magnetic confinement to prevent it from hitting the walls of the container and quickly disappearing. The ALPHA-g experiment aimed to answer how antimatter behaves and revealed that it actually falls the same way that regular matter does.
Antimatter is known for generating high-energy radiation when it encounters normal matter, but contrary to popular belief, it has been shown to be less extreme than expected. For example, positrons, known as antielectrons, are exactly the same as electrons but with opposite charges and “parity.” Physicists had not experimentally confirmed that antimatter behaves the same way as regular matter until the ALPHA-g experiment.
Despite its violent tendencies, antimatter’s nature has raised questions about the definition and properties of matter in physics. The debate revolves around the conception of matter, where rest mass is the simplest definition. Matter encompasses various substances, atoms, molecules, protons, neutrons, electrons, quarks, and neutrinos. However, what constitutes matter becomes blurry when considering massless elementary particles and the contribution of energy to the mass of an object.
Exotic materials, like dark matter and negative mass materials, add complexity to the matter debate. The fact that matter and antimatter exist in unequal amounts, although not fully explained, has led to the formation of stars, galaxies, and planets. Antimatter experiments like ALPHA-g offer insight into matter’s nature and the existence of the universe.
Source: www.sciencefocus.com
