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by grkvlt
3485 days ago
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I have always wondered about whether there might be some kind of similar 'island of stability' with strange particles. Since particles come in three flavours, the normal kind, then ones made of strange/charm quarks and then top/bottom quarks, you could feasibly make 'strange atoms' with the strange equivalents of protons, neutrons and electrons. The same could even be done for top/bottom atoms. As far as I know, though, the half-lives of these strange family particles are too short to let them hang around for long enough. However, if we collect enough together to make e.g. strange-carbon or strange-uranium, maybe the fact that they are bound together as an atomic structure would stabilise them? It's really hard to find anything out about this, as most discussions of strange matter are about things like replacing the electron in a hydrogen atom with a muon, not replacing every particle in a larger atom with its strange counterpart... |
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For example, the neutron decays to a proton, because a proton+electron system has less energy than a neutron. Bind the neutron with a proton, forming deuterium, and suddenly it is stable. The neutron is unstable by only a free MeV, and so the binding to a proton can stabilize it.
All matter is made of up and down quarks. The next lightest quark, the strange quark, is about 100 MeV. It order to stabilize it, there would need to be some binding effect that would bind a strange quark 100 MeV more strongly than an up or down quark. That would be the only way to make the strange quark system be the most stable.
And here we run into the problem that, of the four fundamental forces, none of strong enough and specific enough to the strange quark to do so. The strong nuclear force, which stabilizes the neutron, is the strongest, and only provides that few MeV of binding, not the 100 or so that would be necessary.