nLab neutrino

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Contents

Context

Physics

Fields and quanta

fields and particles in particle physics

and in the standard model of particle physics:

force field gauge bosons

photon - electromagnetic field (abelian Yang-Mills field)
W, Z, B-boson - electroweak field (Yang-Mills field)
gluon - strong nuclear force (Yang-Mills field)
graviton - field of gravity
infraparticle

scalar bosons

Higgs boson, inflaton (scalar field)

matter field fermions (spinors, Dirac fields)

flavors of fundamental fermions in the standard model of particle physics:
generation of fermions	1st generation	2nd generation	3d generation
quarks ( $q$ )
up-type	up quark ( $u$ )	charm quark ( $c$ )	top quark ( $t$ )
down-type	down quark ( $d$ )	strange quark ( $s$ )	bottom quark ( $b$ )
leptons
charged	electron	muon	tauon
neutral	electron neutrino	muon neutrino	tau neutrino

bound states:
mesons	light mesons: pion ( $u d$ ) ρ-meson ( $u d$ ) ω-meson ( $u d$ ) f1-meson a1-meson	strange-mesons: ϕ-meson ( $s \bar s$ ), kaon, K-meson ( $u s$ , $d s$ ) eta-meson ( $u u + d d + s s$ ) charmed heavy mesons*: D-meson ( $u c$ , $d c$ , $s c$ ) J/ψ-meson ( $c \bar c$ )	bottom heavy mesons: B-meson ( $q b$ ) ϒ-meson ( $b \bar b$ )
baryons	nucleons: proton $(u u d)$ neutron $(u d d)$

(also: antiparticles)

effective particles

Goldstone bosons

hadrons (bound states of the above quarks)

meson
- scalar meson
  - σ-meson
  - pion
  - kaon
  - D-meson
  - B-meson
- vector meson
  - ω-meson
  - ρ-meson
  - f1-meson
  - a1-meson
  - b1-meson
  - h1-meson
  - K*-meson
- tensor meson
- quarkonium
  - charmonium
  - ϒ-meson
exotic meson
- XYZ meson
- tetraquark
baryon
- nucleon
  - proton
  - neutron
  - chemical element
    - carbon
    - nitrogen
- Lambda baryon
- pentaquark

solitons

in grand unified theory

minimally extended supersymmetric standard model

superpartners

bosinos:

gravitino - field of supergravity (Rarita-Schwinger field)
gaugino - super Yang-Mills field
gluino

sfermions:

squark

dark matter candidates

WIMP
axion

Exotica

auxiliary fields

Idea
Neutrino masses
History and prediction
Related concepts
References

Idea

The neutrino is one of the fundamental particles/matter fields in the standard model of particle physics.

Neutrino masses

The origin and nature of the observed tiny but non-vanishing neutrino masses remains one of the open problems of the standard model of particle physics. Review includes Fisher-Kayser-McFarland 99.

On neutrino masses and the standard model of particle physics as an effective field theory:

Weinberg 09, p. 15:

I also noted at the same time that interactions between a pair of lepton doublets and a pair of scalar doublets can generate a neutrino mass, which is suppressed only by a factor $M^{-1}$ , and that therefore with a reasonable estimate of $M$ could produce observable neutrino oscillations. The subsequent confirmation of neutrino oscillations lends support to the view of the Standard Model as an effective field theory, with M somewhere in the neighborhood of $10^{16} GeV$ .

In fact this scale is about the GUT scale for grand unified theories, see for instance (Mohapatra 06) for more on this relation, and see at seesaw mechanism.

Detailed matching of parameters of non-supersymmetric $Spin(10)$ -GUT to neutrino masses is discussed in Ohlsson-Pernow 19

History and prediction

The history of the prediction of the neutrino is interesting and may (or may not) contain some general lessons for theoretical physics/mathematical physics.

Before 1930 experiments detected an apparent violation of the conservation law for energy in processes of beta decay.

Back then Niels Bohr proposed that, therefore, apparently the fundamental conservation laws in physics may be violated and possibly only hold statistically over many quantum mechanical processes, but possibly not microscopically.

Opposed to this was the suggestion by Wolfgang Pauli, who insisted that the conservation laws ought to hold true, and that therefore there must be an undetected new fundamental particle created in beta decay, which carries away the apparently missing energy.

Pauli with his argument and suggestion turned out to be right. The missing particle – called the neutrino by Enrico Fermi in 1933 – was finally directly detected in 1956, hence 26 years after its proposal. (Compare maybe to the Higgs boson for which detection came 50 years after prediction.)

Notice that back then, predicting unobserved and possibly practically unobservable fundamental particles was not taken as lightly as in some circles it is these days (e.g. in supersymmetry and/or string theory). In (AP 06, p. 7) Pauli is quoted on this as having said:

I’ve done a terrible thing today, something which no theoretical physicist should ever do. I have suggested something that can never be verified experimentally.

But concerning the motivation for this predictions, notice that back around 1915 Emmy Noether had proven the theorem now named after her – Noether's first theorem – which asserts that symmetries of equations of motion in physics correspond to conservation laws. In particular if a system (notably the forces and interactions of fundamental particles) does not change over time, then Noether's first theorem asserts that the energy of the system must be conserved. The theorem applies as soon as the physics is described by a local Lagrangian/local action functional and the principle of extremal action. This was in principle well established in 1930, even though maybe not as widely appreciated as it could have been. The generalization of this to quantum mechanics and quantum field theory was maybe fully understood only later.

But in view of this theorem, Bohr’s suggestion that energy conservation fails would have implied that fundamental physics is not governed by an action principle, something arguably more dramatic than some violation of some energy conservation might seem.

Today Pauli is widely acknowledged for holding up the conservation laws against Bohr’s proposal, see for instance (AP 06, p. 6), where it says:

Pauli’s belief in the absolute credibility of symmetry principles led him to defend conservation laws even when at that time the empirical evidence was doubtful. His prediction of the neutrino is a great example.

But on the other hand, it seems that Pauli’s respect for the conservation laws was not informed by Noether’s theorem, but rested rather on an intuitive feeling, for in (AP 06, p.5) Pauli is quoted as late as 1953 thus:

I am very much in favour of the general principle to bring empirical conservation laws and invariance properties in connection with mathematical groups of transformations of the laws of nature.

While this does support the correct answer, it seems to be a rather weak way of stating it, given that Noether’s theorem establishes this “connection” as a theorem, already back in 1915.

Similarly, in (AP 06, p. 6) Pauli is quoted as reacting to Bohr’s proposal by saying:

I am myself fairly convinced $[...]$ that Bohr with his corresponding deliberations concerning a violation of energy conservation is entirely on the wrong track! $[...]$ The idea of a violation of the conservation of energy in β-decay is and remains, in my opinion, cheap and very clumsy philosophy.

If Pauli had really been relying on symmetry and the Noether theorem, he could have said “provably wrong” instead of just “cheap and clumsy”. Especially since “clumsy” suggests “possible, even if not enjoyable”, where in fact it is impossible unless the whole foundations of physics are changed.

Related concepts

flavors of fundamental fermions in the standard model of particle physics:
generation of fermions	1st generation	2nd generation	3d generation
quarks ( $q$ )
up-type	up quark ( $u$ )	charm quark ( $c$ )	top quark ( $t$ )
down-type	down quark ( $d$ )	strange quark ( $s$ )	bottom quark ( $b$ )
leptons
charged	electron	muon	tauon
neutral	electron neutrino	muon neutrino	tau neutrino

bound states:
mesons	light mesons: pion ( $u d$ ) ρ-meson ( $u d$ ) ω-meson ( $u d$ ) f1-meson a1-meson	strange-mesons: ϕ-meson ( $s \bar s$ ), kaon, K-meson ( $u s$ , $d s$ ) eta-meson ( $u u + d d + s s$ ) charmed heavy mesons*: D-meson ( $u c$ , $d c$ , $s c$ ) J/ψ-meson ( $c \bar c$ )	bottom heavy mesons: B-meson ( $q b$ ) ϒ-meson ( $b \bar b$ )
baryons	nucleons: proton $(u u d)$ neutron $(u d d)$

References

A discussion of Wolfgang Pauli‘s thoughts leading him to the prediction of the neutrino:

Atmanspacher, Primas, Pauli’s ideas…, 2006 (pdf)
Francesco Vissani, First steps towards understanding neutrinos [arXiv:2310.07834]

Review:

Goran Senjanovic, LHC and the neutrino paradigm, talk at CERN EP seminar 2011 (cern:148714, recording)
Athar et al. Status and Perspectives of Neutrino Physics, IUPAP Neutrino Panel Report (arXiv:2111.07586)
M. Sajjad Athar, A. Fatima, S. K. Singh, Neutrinos and their interactions with matter [arXiv:2206.13792]
Theory of Neutrino Physics – Snowmass TF11 (aka NF08) Topical Group Report [arXiv:2209.07983]
Ken-ichi Hikasa, CPT, Majorana fermions, and particle physics beyond the Standard Model [arXiv:2405.19774]