We know electron by what it does, not by what it is. And even more recently, a Bose-Einstein condensate has been made out of photons. In principle you could make something similar to a laser out of any boson. What these experiments do in making this condensate is cause large numbers of identical boson atoms to all sit as still as a quantum mechanical object possibly can. Something else you can do with boson particles is form a Bose-Einstein condensate, a phenomenon predicted by Einstein back in the 1920’s but only produced in a definitive way in the 1990’s, in Nobel-Prize winning experiments described in the link above. The Higgs field, which is non-zero in our universe and gives mass thereby to the known elementary particles, is a boson field (and its particle is therefore a boson, hence the name Higgs boson that you will hear people use.) The known elementary particles of our world include many fermions - the charged leptons, neutrinos and quarks are all fermions - and many bosons - all of the force carriers, and the Higgs particle(s).Īnother thing boson fields can do is be substantially non-zero on average. If electrons were bosons, chemistry would be unrecognizable! The electrons in an atom occupy different orbits, in different shells around the atomic nucleus, because they cannot all drop down into the same orbit - they are forbidden from doing so because they are fermions. This is the underlying reason for the Pauli exclusion principle that we learn in chemistry class, and has enormous consequences for the periodic table of the elements and for chemistry. Because an electron is a fermion, two electrons cannot orbit an atom in exactly the same way. Two fermions (of the same particle type) are forbidden from doing the same exact thing. All the photons in that beam are in lockstep. For example, a laser is a machine for making large numbers of photons do exactly the same thing, giving a very bright light with a very precise color heading in a very definite direction. Two or more bosons (if they are of the same particle type) are allowed to do the same exact thing. But data over the past 100 years seems to bear it out every known particle in the Standard Model is either a fermion or a boson.Īn example of a boson is a photon. This statement is a mathematical theorem, not an observation from data. In a world where Einstein’s relativity is true, space has three dimensions, and there is quantum mechanics, all particles must be either fermions (named after Italian physicist Enrico Fermi) or bosons (named after Indian physicist Satyendra Nath Bose).
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