![]() ![]() Recreating faux-Big Bang conditions that could form either beauty quarks or heavy neutrinos is the focus of particle accelerators the world over.Īnd detectors in Japan and at CERN are looking for any trace of asymmetry in the particle/anti-particle output as these unstable, heavy particles decay. Theories are great, but science is built on evidence. The amount of excess matter beauty quarks could account for is a little harder to predict because it relies on interactions with a new force or forces that haven't actually been discovered. That's just 10 times more than the amount of leftover matter needed post-Big Bang to give us our universe - a pretty good result in this vast field of unknowns. It's predicted the heavy neutrino (if it exists) would result in one extra matter particle for every billion matter/antimatter pairs. The suspicion is that the antimatter versions of these superheavy particles decay slightly differently from the matter versions. They then quickly decay through a series of steps into smaller, more-stable particles and antiparticles. This means they can only exist in incredibly high-energy environments, and only for an incredibly short time. Like all super-heavy particles, these bits of matter are unstable. (Beauty is its stage name - it also goes by "bottom quark", a name still favoured by older physicists, the British and nine-year-olds).Ī simulation shows traces of a collision of particles. With high-energy photons out of contention, the strongest candidates for a process that gives slightly more matter than antimatter are a couple of incredibly heavy particles of matter - the heavy neutrino and the beauty quark. The standard post-Big Bang production of matter/antimatter from cooling of high-energy photons results in equal amounts of both, so photons are not the source of unevenness. The most straightforward way to end up with slightly more matter than antimatter is to have processes that produce them a bit unevenly. ![]() Bottom quarks and heavy neutrinos weighed in debate You look at how matter and antimatter behaved in the ridiculously high energy environment straight after the Big Bang, and see if there's any oddness that could account for the tiny excess of matter needed to explain all the matter that's here today.Īnd the best way to recreate the high energy big bang environment is by smashing particles together at near light speed in a particle accelerator (like the Large Hadron Collider at CERN) and seeing what falls out. So how do you look for the mysterious factor that led to our leftover matter? That imbalance - called the matter/antimatter asymmetry - gave us the leftover matter that forms everything in the universe, from galaxies and hydrogen clouds to you and slime moulds.įinding the cause of the imbalance means finding a brand new bit of physics - like a new particle or force - and it's one of the more exciting and challenging jobs in particle physics right now. Something led to a tiny imbalance in the matter/antimatter numbers at the beginning of time, with matter slightly in the lead. ![]() ( Reuters: Pierre Albouy)Īnd unless we're all part of some universe-wide delusion, that's clearly not right. The Large Hadron Collider is trying to replicate conditions of the big bang to measure what happened to "missing" antimatter. ![]()
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