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The equivalent vector boson approximation at threshold energies
TL;DR: In this paper, a simple derivation of the distributions of the equivalent electroweak vector bosons in leptons and quarks is presented, and the applicability of the equivalence vector boson approximation at relatively low energies close to the $W$ and $Z$ boson thresholds is demonstrated.
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Abstract: A simple derivation of the distributions of the equivalent electroweak vector bosons in leptons and quarks is presented. The applicability of the equivalent vector boson approximation at relatively low energies close to the $W$ and $Z$ boson thresholds is demonstrated. It is shown that the threshold correction to the distribution functions emerges naturally in the theory. Implications of the results for processes with the emission of the gauge bosons are discussed.
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Citations
Charged lepton beams as a source of effective neutrinos.
TL;DR: In this paper, the authors proposed a method of studying neutrino interactions based on the fact that a charged lepton is able to manifest itself effectively, with a certain probability, as neutrinos.
1
Probing the Glashow resonance at electron-positron colliders
TL;DR: The Glashow resonance is a rapid enhancement of the cross section for scattering of electron antineutrinos on electrons at the $W^-$ boson production threshold due to the $s$-channel contribution as discussed by the authors.
Probing the Glashow resonance at electron–positron colliders
TL;DR: The Glashow resonance is a rapid enhancement of the cross-section for scattering of electron antineutrinos on electrons at the W− boson production threshold due to the s-channel contribution.
References
•Book
Electroweak Interactions: An Introduction to the Physics of Quarks and Leptons
Peter Renton
- 01 Jan 1990
TL;DR: In this paper, the authors propose a quantum field theory for quantum electrodynamics, from Fermi theory to the standard model and beyond, with a focus on weak hadronic currents and electroweak interference effects.
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