| 11. | During these processes, the W boson charge induces electron or positron emission or absorption, thus causing nuclear transmutation.
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| 12. | The W bosons can subsequently decay either into a quark and an antiquark or into a charged lepton and a neutrino.
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| 13. | In December 2016, ATLAS presented a measurement of the W boson mass, rearching the precision of analyses done at the Tevatron.
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| 14. | The Feynman diagram for beta decay of a neutron into a proton, electron, and electron antineutrino via an intermediate heavy W boson
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| 15. | As for the W and Z bosons, if I'm understanding the article correctly, the W bosons interact electromagnetically but the Z doesn't.
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| 16. | Beta decay is a consequence of the W boson and the creation of an electron / antineutrino or positron / neutrino pair.
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| 17. | Here is the coupling constant of the weak interaction, and is the mass of the W boson which mediates the decay in question.
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| 18. | This theory has made a number of predictions, including a prediction of the masses of the Z and W bosons before their discovery.
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| 19. | These are the parameters that are most easily produced and detected ( in the case of neutrinos, by weak interactions involving the W boson ).
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| 20. | Similarly, the are antiparticles of each other, but the fundamental W bosons are their own antiparticles in the same sense as the other gauge bosons.
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