If neutrinos are Majorana particles, one way of explaining their small masses is the seesaw mechanism.
Now say I'd like my neutrinos to be Dirac, for symmetry to the quark sector. What mechanisms exist to explain Dirac neutrinos' mass?
Also, maybe interesting in this context: Why is the neutrino mass considered more in need on an explanation than the electron mass? Could the masses of the Fermions (I mean their terms in the Lagrangian, as well as their values) maybe all of the same origin?
Answer
You can generate Dirac neutrino masses through the Higgs mechanism by introducing right handed neutrinos (in the same way you generate masses for the upper quarks). Since neutrino masses are at the sub-$eV$ scale, this means that the Yukawa couplings have to be unnaturally small, of order $10^{-12}$.
People prefer to keep $\mathcal{O}(1)$ Yukawa's and blame the unusual smallness of neutrino masses on the fact that these are neutral particles. If neutrinos happen to coincide with anti-neutrinos, then lepton number is violated by two units (global symmetries are not sacred). In this case it is natural to introduce a large Majorana mass scale $\Lambda$ which ends up suppressing the neutrino masses via See-saw mechanism as $\langle\phi\rangle^2/\Lambda$. People like this because this large scale turns out be quite close to the Grand Unification scale.
An alternative way to generate small masses for neutrinos without introducing a large Majorana scale or Right handed neutrinos is through radiative corrections. You can assume that neutrino masses are zero at the tree level (as in the SM) and generate small non-zero masses at 1 or 2-loop level by introducing new heavy scalar fields.
One nice example is the Zee model, where the SM scalar sector is extended to include a second Higgs doublet $\phi_2$ and a Higgs singlet $\omega$. The Loop producing neutrino masses is given by
These models also break lepton number, but generally at a much lower scale. (e.g. at TeV scale).
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