The neutrino theory of light is the proposal that the photon is a composite particle formed of a neutrino–antineutrino pair. It is based on the idea that emission and absorption of a photon corresponds to the creation and annihilation of a particle–antiparticle pair. The neutrino theory of light is not currently accepted as part of mainstream physics, as according to the Standard Model the photon is an elementary particle, a gauge boson.
In the past, many particles that were once thought to be elementary such as protons, neutrons, pions, and kaons have turned out to be composite particles. In 1932, Louis de Broglie[1] [2] [3] suggested that the photon might be the combination of a neutrino and an antineutrino. During the 1930s there was great interest in the neutrino theory of light and Pascual Jordan,[4] Ralph Kronig, Max Born, and others worked on the theory.
In 1938, Maurice Pryce[5] brought work on the composite photon theory to a halt. He showed that the conditions imposed by Bose–Einstein commutation relations for the composite photon and the connection between its spin and polarization were incompatible. Pryce also pointed out other possible problems,
“In so far as the failure of the theory can be traced to any one cause it is fair to say that it lies in the fact that light waves are polarized transversely while neutrino ‘waves’ are polarized longitudinally,”
and lack of rotational invariance. In 1966, V. S. Berezinskii reanalyzed Pryce's paper, giving a clearer picture of the problem that Pryce uncovered.[6]
Starting in the 1960s work on the neutrino theory of light resumed, and there continues to be some interest in recent years.[7] [8] [9] [10] Attempts have been made to solve the problem pointed out by Pryce, known as Pryce's theorem, and other problems with the composite photon theory. The incentive is seeing the natural way that many photon properties are generated from the theory and the knowledge that some problems exist[11] [12] with the current photon model. However, there is no experimental evidence that the photon has a composite structure.
Some of the problems for the neutrino theory of light are the non-existence for massless neutrinos with both spin parallel and antiparallel to their momentum outside the Einstein-Cartan torsion[13] [14] and the fact that composite photons are not bosons.[15] Attempts to solve some of these problems will be discussed, but the lack of massless neutrinos outside the Einstein-Cartan torsion[16] [17] makes it impossible outside the Einstein-Cartan torsion[18] [19] to form a massless photon with this theory. The neutrino theory of light is not considered to be part of mainstream physics.
It is possible to obtain transversely polarized photons from neutrinos.[20] [21]
The neutrino field satisfies the Dirac equation with the mass set to zero,
\gamma\mup\mu\Psi=0.
The gamma matrices in the Weyl basis are:
\gamma0=\left(\begin{array}{cccc} 0&0&1&0\\ 0&0&0&1\\ 1&0&0&0\\ 0&1&0&0 \end{array}\right), \gamma1=\left(\begin{array}{cccc} 0&0&0&1\\ 0&0&1&0\\ 0&-1&0&0\\ -1&0&0&0 \end{array}\right),
\gamma2=\left(\begin{array}{cccc} 0&0&0&-i\\ 0&0&i&0\\ 0&i&0&0\\ -i&0&0&0 \end{array}\right), \gamma3=\left(\begin{array}{cccc} 0&0&1&0\\ 0&0&0&-1\\ -1&0&0&0\\ 0&1&0&0 \end{array}\right).
The matrix
\gamma0
\gammak
\gamma\mu\gamma\nu+\gamma\nu\gamma\mu=2η\muI
η\mu
(+---)
I
The neutrino field is given by,
\Psi(x)={1\over\sqrt{V}}\sumk\left\{ \left[a1(k)
| +1 | |
| u | |
| +1 |
(k)+a2(k)
| +1 | |
| u | |
| -1 |
(k) \right]ei\right.
\left.+\left[
| \dagger(k) | |
| c | |
| 1 |
| -1 | |
| u | |
| -1 |
(-k) +
| \dagger(k) | |
| c | |
| 2 |
| -1 | |
| u | |
| +1 |
(-k)\right]e-i\right\},
where
kx
k ⋅ x-k0t
a1
c1
\nu1
\overline\nu1
a2
c2
\nu2
\overline\nu2
\nu1
\nu2
u
| +1 | |
| u | |
| +1 |
(p)=\sqrt{{E+p3}\over2E} \left(\begin{array}{c} 1\\ {{p1+ip2}\over{E+p3}}\\ 0\\ 0 \end{array}\right),
| -1 | |
| u | |
| -1 |
(p)=\sqrt{{E+p3}\over2E} \left(\begin{array}{c} {{-p1+ip2}\over{E+p3}}\\ 1\\ 0\\ 0 \end{array}\right),
| -1 | |
| u | |
| +1 |
(p)=\sqrt{{E+p3}\over2E} \left(\begin{array}{c} 0\\ 0\\ 1\\ {{p1+ip2}\over{E+p3}} \end{array}\right),
| +1 | |
| u | |
| -1 |
(p)=\sqrt{{E+p3}\over2E} \left(\begin{array}{c} 0\\ 0\\ {{-p1+ip2}\over{E+p3}}\\ 1 \end{array}\right).
The neutrino spinors for negative momenta are related to those of positive momenta by,
| +1 | |
| u | |
| +1 |
(-p)=
| -1 | |
| u | |
| -1 |
(p),
| -1 | |
| u | |
| -1 |
(-p)=
| +1 | |
| u | |
| +1 |
(p),
| +1 | |
| u | |
| -1 |
(-p)=
| -1 | |
| u | |
| +1 |
(p),
| -1 | |
| u | |
| +1 |
(-p)=
| +1 | |
| u | |
| -1 |
(p).
De Broglie[1] and Kronig[20] suggested the use of a local interaction to bind the neutrino–antineutrino pair. (Rosen and Singer[22] have used a delta potential interaction in forming a composite photon.) Fermi and Yang[23] used a local interaction to bind a fermion–antiferminon pair in attempting to form a pion. A four-vector field can be created from a fermion–antifermion pair,[24]
\Psi\dagger\gamma0\gamma\mu\Psi.
Forming the photon field can be done simply by,
A\mu(x)=\sump{-1\over2\sqrt{Vp0}}\left\{ \left[QR(p)
| -1 | |
| u | |
| -1 |
(p)\dagger\gamma0\gamma\mu
| +1 | |
| u | |
| +1 |
(p) +QL(p)
| +1 | |
| u | |
| +1 |
(p)\dagger\gamma0\gamma\mu
| -1 | |
| u | |
| -1 |
(p)\right]ei\right.
\left.+
| \dagger(p) | |
| \left[Q | |
| R |
| +1 | |
| u | |
| +1 |
(p)\dagger\gamma0\gamma\mu
| -1 | |
| u | |
| -1 |
(p) +
| \dagger(p) | |
| Q | |
| L |
| -1 | |
| u | |
| -1 |
(p)\dagger\gamma0\gamma\mu
| +1 | |
| u | |
| +1 |
(p) \right]e-i\right\}, (1)
px=p ⋅ x-p0t=p ⋅ x-Et
The annihilation operators for right-handed and left-handed photons formed of fermion–antifermion pairs are defined as,[25] [26] [27] [28]
QR(p)=\sumkF\dagger(k) \left[c1(p/2-k)a1(p/2+k) +c2(p/2+k)a2(p/2-k)\right]
QL(p)=\sumkF\dagger(k) \left[c2(p/2-k)a2(p/2+k) +c1(p/2+k)a1(p/2-k),\right].
F(k)
\sumk\left|F(k)\right|2=1.
The polarization vectors corresponding to the combinations used in Eq. (1) are,
| 1( | |
| \epsilon | |
| \mu |
p)={-1\over\sqrt{2}}
| -1 | |
| [u | |
| -1 |
(p)]\dagger \gamma0\gamma\mu
| +1 | |
| u | |
| +1 |
(p),
| 2( | |
| \epsilon | |
| \mu |
p)={-1\over\sqrt{2}}
| +1 | |
| [u | |
| +1 |
| \dagger \gamma | |
| (p)] | |
| 0 |
\gamma\mu
| -1 | |
| u | |
| -1 |
(p).
Carrying out the matrix multiplications results in,
| 1(p) | |
| \epsilon | |
| \mu |
={1\over\sqrt{2}}\left({{-ip1p2+E2+p3E
| 2} | |
| -p | |
| 1 |
\over{E(E+p3)}}, {{-p1p2+iE2+ip3E-
| 2 | |
| ip | |
| 2 |
} \over{E(E+p3)}}, {{-p1-ip2}\overE},0\right),
| 2(p) | |
| \epsilon | |
| \mu |
={1\over\sqrt{2}}\left({{ip1p2+E2+p3E
| 2} | |
| -p | |
| 1 |
\over{E(E+p3)}}, {{-p1p2-iE2-ip3E+
| 2 | |
| ip | |
| 2 |
} \over{E(E+p3)}}, {{-p1+ip2}\overE},0\right), (2)
| 1(p) | |
| \epsilon | |
| 0 |
| 2(p) | |
| \epsilon | |
| 0 |
For massless fermions the polarization vectors depend only upon the direction of
p
n=p/|p|
| 1(n) | |
| \epsilon | |
| \mu |
={1\over\sqrt{2}}\left({{-in1n2+1+n3
| 2} | |
| -n | |
| 1 |
\over{1+n3}}, {{-n1n2+
| 2 | |
| in | |
| 1 |
+
| 2 | |
| in | |
| 3 |
+in3} \over{1+n3}}, -n1-in2,0\right),
| 2(n) | |
| \epsilon | |
| \mu |
={1\over\sqrt{2}}\left({{in1n2+1+n3
| 2} | |
| -n | |
| 1 |
\over{1+n3}}, {{-n1n2-
| 2 | |
| in | |
| 1 |
-
| 2 | |
| in | |
| 3 |
-in3} \over{1+n3}}, -n1+in2,0\right).
| j(p) | |
| \epsilon | |
| \mu |
⋅
| j* | |
| \epsilon | |
| \mu |
(p)=1,
| j(p) | |
| \epsilon | |
| \mu |
⋅
| k* | |
| \epsilon | |
| \mu |
(p)=0 for k\nej.
The Lorentz-invariant dotproducts of the internal four-momentum
p\mu
p\mu
| 1(p) | |
| \epsilon | |
| \mu |
=0,
p\mu
| 2(p) | |
| \epsilon | |
| \mu |
=0. (3)
In three dimensions,
p ⋅
| \epsilon1(p) |
= p ⋅
| \epsilon2(p) |
=0,
| \epsilon1(p) |
| x \epsilon2(p)= |
-ip/p0,
p x
| \epsilon1(p)=-i |
| p | ||
|
p x
| \epsilon2(p)= |
i
| p | ||
|
(4)
In terms of the polarization vectors,
A\mu(x)
A\mu(x)=\sump{1\over\sqrt{2Vp0}}\left\{ \left[QR(p)
| 1(p) | |
| \epsilon | |
| \mu |
+QL(p) \epsilon
| 2(p) \right]e | |
| \mu |
i\right.
\left.+
| \dagger(p) | |
| \left[Q | |
| R |
| 1* | |
| \epsilon | |
| \mu |
(p) +
| \dagger(p) | |
| Q | |
| L |
| 2* | |
| \epsilon | |
| \mu |
(p) \right]e-i\right\}. (5)
The electric field
E~
H~
E(x)=-{\partialA(x)\over\partialt},
H(x)=\nabla x A(x). (6)
Applying Eq. (6) to Eq. (5), results in,
E\mu(x)=i\sump{\sqrt{p0}\over\sqrt{2V}}\left\{ \left[QR(p)
| 1(p) + | |
| \epsilon | |
| \mu |
QL(p)
| 2(p) | |
| \epsilon | |
| \mu |
\right]ei\right.
\left.-
| \dagger(p) | |
| \left[Q | |
| R |
| 1* | |
| \epsilon | |
| \mu |
(p) +
| \dagger(p) | |
| Q | |
| L |
| 2* | |
| \epsilon | |
| \mu |
(p), \right]e-i\right\}.
H\mu(x)=\sump{\sqrt{p0}\over\sqrt{2V}}\left\{ \left[QR(p)
| 1(p) - | |
| \epsilon | |
| \mu |
QL(p)
| 2(p) | |
| \epsilon | |
| \mu |
\right]ei\right.
\left.+
| \dagger(p) | |
| \left[Q | |
| R |
| 1* | |
| \epsilon | |
| \mu |
(p) -
| \dagger(p) | |
| Q | |
| L |
| 2* | |
| \epsilon | |
| \mu |
(p), \right]e-i\right\}.
Maxwell's equations for free space are obtained as follows:
\partialE1(x)/\partialx1= i\sump{\sqrt{p0}\over\sqrt{2V}}\left\{ \left[QR(p)p1
| 1(p) + | |
| \epsilon | |
| 1 |
QL(p)p1
| 2(p) | |
| \epsilon | |
| 1 |
\right]ei\right.
\left.+
| \dagger(p) | |
| \left[Q | |
| R |
p1
| 1* | |
| \epsilon | |
| 1 |
(p) +
| \dagger(p) | |
| Q | |
| L |
p1
| 2* | |
| \epsilon | |
| 1 |
(p) \right]e-i\right\}.
\partialE1(x)/\partialx1+\partial E2(x)/\partialx2+ \partialE3(x)/\partialx3
p1
| 1(p) | |
| \epsilon | |
| 1 |
+p2
| 1(p) + | |
| \epsilon | |
| 2 |
p3
| 1(p) | |
| \epsilon | |
| 3 |
\nabla ⋅ E(x)=0,
\nabla ⋅ H(x)=0.
H
The expression
\nabla x E(x)
p x
| \epsilon1(p) |
\partialH(x)/\partialt
ip0
| \epsilon1(p) |
\nabla x E(x)=-\partialH(x)/\partialt,
\nabla x H(x)=\partialE(x)/\partialt.
Although the neutrino field violates parity and chargeconjugation,[29]
E
H
PE(x,t)P-1=-E(-x,t),
PH(x,t)P-1=H(-x,t),
CE(x,t)C-1=-E(x,t),
CH(x,t)C-1=-H(x,t).
A\mu
\partialA\mu/\partialx\mu=0
Although many choices for gamma matrices can satisfy the Dirac equation, itis essential that one use the Weyl representation in order to get the correct photon polarization vectors and
E
H
To compute the commutation relations for the photon field, one needs the equation,
| 2 | |
| \sum | |
| j=1 |
| j(p) | |
| \epsilon | |
| \mu |
| j* | |
| \epsilon | |
| \nu |
(p) ==
| 2 | |
| \sum | |
| j==1 |
| j* | |
| \epsilon | |
| \mu |
(p)
| j(p) = | |
| \epsilon | |
| \nu |
\delta\mu-{p\mup\nu\overE2}.
If the momentum is along the third axis,
| 1(n) | |
| \epsilon | |
| \mu |
| 2(n) | |
| \epsilon | |
| \mu |
| 1(n) | |
| \epsilon | |
| \mu |
={1\over\sqrt{2}}(1,i,0,0),
| 2(n) | |
| \epsilon | |
| \mu |
={1\over\sqrt{2}}(1,-i,0,0).
Although composite photons satisfy many properties of real photons, there are major problems with this theory.
It is known that a photon is a boson.[31] Does the composite photon satisfy Bose–Einstein commutation relations? Fermions are defined as the particles whose creation and annihilation operators adhere to the anticommutation relations
\{a(k),a(l)\}=0,
\{a\dagger(k),a\dagger(l)\}=0,
\{a(k),a\dagger(l)\} =\delta(k-l),
while bosons are defined as the particles that adhere to the commutation relations
\left[b(k),b(l)\right]=0,
\left[b\dagger(k),b\dagger(l)\right]=0,
\left[b(k),b\dagger(l)\right] =\delta(k-l). (7)
The creation and annihilation operators of composite particles formed of fermion pairs adhere to the commutation relations of the form[25] [26] [27] [28]
\left[Q(k),Q(l)\right]=0,
\left[Q\dagger(k),Q\dagger(l)\right]=0,
\left[Q(k),Q\dagger(l)\right] =\delta(k-l)-\Delta(k,l). (8)
with
\Delta(p\prime,p)= \sumkF\dagger(k)\left[ F(p\prime/2-p/2+k) a\dagger(p-p\prime/2-k) a(p\prime/2-k)\right.
\left. +F(p/2-p\prime/2+k) c\dagger(p-p\prime/2+k) c(p\prime/2+k)\right]. (9)
For Cooper electron pairs,[27] "a" and "c" represent different spin directions. For nucleon pairs (the deuteron),[25] [26] "a" and "c" represent proton and neutron. For neutrino–antineutrino pairs,[28] "a" and "c" represent neutrino and antineutrino. The size of the deviations from pure Bose behavior,
\Delta(p\prime,p),
depends on the degree of overlap of the fermion wave functions and the constraints of the Pauli exclusion principle.
If the state has the form
|\Phi\rangle=
| ||
| a |
| ||
| ||
| ||
| ||
| ||
\rangle
then the expectation value of Eq. (9) vanishes for
p\prime\nep
\Delta(p\prime,p)
\Delta(p\prime,p)= \delta(p\prime-p) \sumk\left|F(k)\right|2 \left[a\dagger(p/2-k) a(p/2-k)\right.
\left. +c\dagger(p/2+k) c(p/2+k)\right].
Using the fermion number operators
na(k)
nc(k)
\Delta(p\prime,p)= \delta(p\prime-p) \sumk\left|F(k)\right|2 \left[na(p/2-k) +nc(p/2+k) \right]
=\delta(p\prime-p) \sumk\left[\left|F(p/2-k)\right|2 na(k)+\left|F(k-p/2)
| 2 n | |
| \right| | |
| c(k) |
\right]
=\delta(p\prime-p) \overline{\Delta}(p,p)
k
F(p/2-k)
F(k-p/2)
De Broglie did not address the problem of statistics for the composite photon. However, "Jordan considered the essential part of the problem was to construct Bose–Einstein amplitudes from Fermi–Dirac amplitudes", as Pryce[5] noted. Jordan[4] "suggested that it is not the interaction between neutrinos and antineutrinos that binds them together into photons, but rather the manner in which they interact with charged particles that leads to the simplified description of light in terms of photons."
Jordan's hypothesis eliminated the need for theorizing an unknown interaction, but his hypothesis that the neutrino and antineutrino are emitted in exactly the same direction seems rather artificial as noted by Fock.[32] His strong desire to obtain exact Bose–Einstein commutation relations for the composite photon led him to work with a scalar or longitudinally polarized photon. Greenberg and Wightman[33] have pointed out why the one-dimensional case works, but the three-dimensional case does not.
In 1928, Jordan noticed that commutation relations for pairs of fermions were similar to those for bosons.[34] Compare Eq. (7) with Eq. (8). From 1935 until 1937, Jordan, Kronig, and others[35] tried to obtain exact Bose–Einstein commutation relations for the composite photon. Terms were added to the commutation relations to cancel out the delta term in Eq. (8). These terms corresponded to "simulated photons". For example, the absorption of a photon of momentum
p
p+k
k
In 1938, Pryce[5] showed that one cannot obtain both Bose–Einstein statistics and transversely polarized photons from neutrino–antineutrino pairs. Construction of transversely polarized photons is not the problem.[36] As Berezinski[6] noted, "The only actual difficulty is that the construction of a transverse four-vector is incompatible with the requirement of statistics." In some ways Berezinski gives a clearer picture of the problem. A simple version of the proof is as follows:
The expectation values of the commutation relations for composite right and left-handed photons are:
\left[
| \prime | |
| Q | |
| R(p |
), QR(p)\right]=0, \left[
| \prime | |
| Q | |
| L(p |
), QL(p)\right]=0,
\left[
| \prime | |
| Q | |
| R(p |
| \dagger(p) | |
| ), Q | |
| R |
\right] =\delta(p\prime-p) (1-{\overline\Delta12
\left[
| \prime | |
| Q | |
| L(p |
| \dagger(p) | |
| ), Q | |
| L |
\right] =\delta(p\prime-p) (1-{\overline\Delta21
\left[
| \prime | |
| Q | |
| R(p |
), QL(p)\right]=0, \left[
| \prime | |
| Q | |
| R(p |
| \dagger(p) | |
| ), Q | |
| L |
\right]=0, (10)
where
{\overline\Delta12
The deviation from Bose–Einstein statistics is caused by
\overline\Delta12(p,p)
\overline\Delta21(p,p)
Linear polarization photon operators are defined by
\xi(p)={1\over\sqrt{2}}\left[QL(p) +QR(p)\right],
η(p)={i\over\sqrt{2}}\left[QL(p) -QR(p)\right]. (12)
[\xi(p\prime),η\dagger(p)] ={i\over2}\delta(p\prime-p) [\overline\Delta21(p,p) -\overline\Delta12(p,p)], (13)
For the composite photon to obey Bose–Einstein commutation relations, at the very least,
[\xi(p\prime),η\dagger(p)] =0 (14)
\sumk\left[ \left|F(k-p/2)
| 2 (n | |
| \right| | |
| a1 |
(k)+nc2(k)-na2(k)-nc1(k)) \right.
\left.+\left|F(p/2-k)\right|2 (nc1(k)+na2(k)-nc2(k)-na1(k)) \right]
gives zero when applied to any state vector. Thus, all the coefficients of
na1(k)
nc1(k)
F(k)=0
Perkins[21] [28] reasoned that the photon does not have to obey Bose–Einstein commutation relations, because the non-Bose terms are small and they may not cause any detectable effects. Perkins[12] noted, "As presented in many quantum mechanics texts it may appear that Bose statistics follow from basic principles, but it is really from the classical canonical formalism. This is not a reliable procedure as evidenced by the fact that it gives the completely wrong result for spin-1/2 particles." Furthermore, "most integral spin particles (light mesons, strange mesons, etc.) are composite particles formed of quarks. Because of their underlying fermion structure, these integral spin particles are not fundamental bosons, but composite quasibosons. However, in the asymptotic limit, which generally applies, they are essentially bosons. For these particles, Bose commutation relations are just an approximation, albeit a very good one. There are some differences; bringing two of these composite particles close together will force their identical fermions to jump to excited states because of the Pauli exclusion principle."
Brzezinski in reaffirming Pryce's theorem argues that commutation relation (14) is necessary for the photon to be truly neutral. However, Perkins[28] has shown that a neutral photon in the usual sense can be obtained without Bose–Einstein commutation relations.
The number operator for a composite photon is defined as
N(p)=Q\dagger(p)Q(p).
Lipkin[25] suggested for a rough estimate to assumethat
F(k)=1/\Omega
\Omega
Perkins[12] showed that the effect of the composite photon'snumber operator acting on a state of
m
N(p)(Q\dagger(p))m|0\rangle =\left(m-{m(m-1)\over\Omega} \right)(Q\dagger(p))m|0\rangle,
N(p)|0\rangle=0
\Omega
| \dagger(p)|n | |
| Q | |
| p |
\rangle =\sqrt{(np+1) \left(1-{np\over\Omega}\right)} |np+1\rangle,
Q(p)|np\rangle =\sqrt{np \left(1-{(np-1)\over\Omega}\right)} |np-1\rangle, (15)
where
|np\rangle
np
p
Q\dagger(p)
np
Q\dagger(p)|0\rangle=|1p\rangle,
Q(p)|1p\rangle=|0\rangle,
\Omega
The main evidence indicating that photons are bosons comes from the Blackbody radiation experiments which are in agreement with Planck's distribution. Perkins[12] calculated the photon distribution for Blackbody radiation using the second quantization method,[37] but with a composite photon.
The atoms in the walls of the cavity are taken to be a two-level system with photons emitted from the upper level β and absorbed at the lower level α. The transition probability for emission of a photon is enhanced when np photons are present,
w\alpha(np+1\leftarrownp)=(np+1)\left(1-{np\over\Omega}\right)w\alpha(1p\leftarrow0), (16)
w(np-1\leftarrownp)=np\left(1-{np-1\over\Omega}\right)w(0\leftarrow1p). (17)
w(0\leftarrow1p)=w(1p\leftarrow0),
{w\alpha(np+1\leftarrownp)\overw(np-1\leftarrownp)}={(np+1)\left(1-{np\over\Omega}\right)\overnp\left(1-{(np-1)\over\Omega}\right)}.
The probability of finding the system with energy E is proportional to e-E/kT according to Boltzmann's distribution law. Thus, the equilibrium between emission and absorption requires that,
w\alpha(np+1\leftarrownp)
| -E\beta/kT | |
| e |
=w(np-1\leftarrownp)
| -E\alpha/kT | |
| e |
,
\omegap=E\beta-E\alpha
np={2\overu+(u+2)/\Omega+\sqrt{u2(1+2/\Omega)+(u+2)2/\Omega2}},
u=
| \omegap/kT | |
| e |
-1
\Omega(\omegap/kT)\gg1
np={1\over
| \omegap/kT | |
| e |
\left(1+{1\over\Omega}\right)-1}.
This equation differs from Planck's law because of the
1/\Omega
Experimental results show that only left-handed neutrinosand right-handed antineutrinos exist. Three sets of neutrinoshave been observed,[39] [40] one that is connected with electrons, one with muons, and one with tau leptons.[41]
In the standard model the pion and muon decay modes are:
| → | + | ||||||
| → | + | + |
To form a photon, which satisfies parity and charge conjugation, two sets of two-component neutrinos (i.e., right-handed and left-handed neutrinos) are needed. Perkins (see Sec. VI of Ref.[21]) attempted to solve this problem by noting that the needed two sets of two-component neutrinos would exist if the positive muon is identified as the particle and the negative muon as the antiparticle. The reasoning is as follows: let 1 be the right-handed neutrino and 2 the left-handed neutrino with their corresponding antineutrinos (with opposite helicity). The neutrinos involved in beta decay are 2 and 2, while those for π–μ decay are 1 and 1. With this scheme the pion and muon decay modes are:
| → | + | 1 | |||||
| → | + | 2 | + | 1 |
There is convincing evidence that neutrinos have mass. In experiments at the SuperKamiokande researchers[15] have discovered neutrino oscillations in which one flavor of neutrino changed into another. This means that neutrinos have non-zero mass outside the Einstein-Cartan torsion.[42] [43] Since massless neutrinos are needed to form a massless photon, a composite photon is not possible outside the Einstein-Cartan torsion.[44] [45]