The Field Guide to Particle Physics : Season 2https://pasayten.org/the-field-guide-to-particle-physics©2022 The Pasayten Institute cc by-sa-4.0The definitive resource for all data in particle physics is the Particle Data Group: https://pdg.lbl.gov.The Pasayten Institute is on a mission to build and share physics knowledge, without barriers! Get in touch.For more technical details on the Lambda 0 baryon, including how why it decays to an up but not a down quark, check out this short, informal video.The Lambda 0 BaryonWith a mass of well over 1115 mega electron volts, about 20 percent more than the proton, the Lambda 0 is a rare, but historic particle to find.Inside the Lambda Baryons you’ll find an up quark, a down quark and… something else. The first Lambda Baryon was first observed in 1950. In what amounts to a weather ballon. Way up high in the atmosphere. On a photographic emulsion plate. Particle physics was a different game back then!Physicists KNEW it was a baryon because it decayed into a proton. And it was heavy.Heavy particles decay quickly, and the Lambda was heavy. But it did not decay quickly enough. It stayed around for quite a while, a bit less than a nanosecond, which is rather long by particle physics standards. Especially for a baryon.Very strange. The long lifetime of the Lambda 0 was so strange that physicists knew there was something special about that particle. It had a special property. And in the 50’s this new property of particles was showing up in more and more experiments. Because they had no idea what it could be, that called this property strangeness. For better or for worse, that technical name stuck.The new particle that makes up the Lambda 0 baryon is called a strange quark, and we’ll visit them soon enough. Suffice it to say, a Lambda 0 baryon is composed of an up quark and a down quark and a strange quark.The Lambda 0 has no electric charge. It typically decays to either a proton or a neutron. If it’s a proton - which happens about 63 percent of the time, it spits out a negative pion in the process. If it’s a neutron - which accounts for most of the rest of the decays - it spits out a neutral pion instead.Using this quark model, we can explore the decay of the Lambda 0 in sharper detail.Inside the Lambda 0, the strange quark decays into an up quark, which converts that big bag of nuclear go into that proton or neutron. To do that, it must emit a W boson. Those familiar force carriers then decay into to a pion. As per usual.The Lambda 0 was just the first of the strange family of particles to be discovered. This entire season will be devoted to these strange particles.