Lepton number

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In high energy physics, the lepton number is the number of leptons minus the number of antileptons.

In equation form,

L = n_{\ell} - n_{\overline{\ell}}

so all leptons have assigned a value of +1, antileptons −1, and non-leptonic particles 0. Lepton number (sometimes also called lepton charge) is an additive quantum number, which means that its sum is preserved in interactions (as opposed to multiplicative quantum numbers such as parity, where the product is preserved instead).

Beside the leptonic number, leptonic family numbers are also defined:

  • the electronic number Le for the electron and the electronic neutrino;
  • the muonic number Lμ for the muon and the muonic neutrino;
  • the tauonic number Lτ for the tauon and the tauonic neutrino;

with the same assigning scheme as the leptonic number: +1 for particles of the corresponding family, −1 for the antiparticles, and 0 for leptons of other families or non-leptonic particles.

Contents

Many models, including the Standard Model of particle physics rely on lepton number conservation: the lepton number stays the same through an interaction. For example, in the beta decay:

\begin{matrix} & n & \rightarrow & p & + & e^{-} & + & {\overline{\nu}}_e \\ L: & 0 & = & 0 & + & 1 & - & 1 \end{matrix}

The lepton number before the reaction is 0 (the neutron, n, is a baryon and therefore there are no leptons before), while the lepton number after the reaction is 0 for the proton +1 for the electron (a lepton) −1 for the antineutrino (an antilepton). Thus the lepton number is zero after the decay, and so is conserved.

The lepton family numbers arise from the fact that lepton number is usually conserved in each leptonic family. For example, almost 100% of the time the muon decays as:

\begin{matrix} & \mu & \rightarrow & e^{-} & + & {\overline{\nu}}_e & + & \nu_{\mu} \\ L: & 1 & = & 1 & - & 1 & + & 1 \\ L_e: & 0 & = & 1 & - & 1 & + & 0 \\ L_{\mu}: & 1 & = & 0 & + & 0 & + & 1 \end{matrix}

thus preserving the electronic and muonic numbers. This means that a lepton family number conservation law exist for each one of Le, Lμ and Lτ.

In the Standard Model, leptonic family number (LF) would be preserved if neutrinos were massless. Since neutrinos do have a tiny nonzero mass, neutrino oscillation has been observed, and conservation laws for LF are therefore only approximate. This means the conservation laws are violated, although because of the smallness of the neutrino mass they still hold to a very large degree for interactions containing charged leptons. However, the lepton number conservation law must still hold (under the Standard Model). Thus, it is possible to see rare muon decays such as:

\begin{matrix} & \mu & \rightarrow & e^{-} & + & \nu_e & + & \overline{\nu}_{\mu} \\ L: & 1 & = & 1 & + & 1 & - & 1 \\ L_e: & 0 & \ne & 1 & + & 1 & + & 0 \\ L_{\mu}: & 1 & \ne & 0 & + & 0 & - & 1 \end{matrix}

Because the lepton number conservation law in fact is violated by chiral anomalies, there are problems applying this symmetry universally over all energy scales. However, the quantum number B−L is much more likely to work and is seen in different models such as the Pati-Salam model.

  • Griffiths, David J. (1987). Introduction to Elementary Particles. Wiley, John & Sons, Inc. ISBN 0-471-60386-4. 
  • Tipler, Paul; Llewellyn, Ralph (2002). Modern Physics (4th ed.). W. H. Freeman. ISBN 0-7167-4345-0. 
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