Explaining Ratios of Lepton & Quark Masses (PDF)

Summary

This document explains the ratios of masses of leptons and quarks using a new equation for Yukawa couplings. It details a new methodology based on the running of the fine-structure constant and aims to predict the masses of left-chiral neutrinos and upper limits of right-chiral neutrinos.

Full Transcript

EXPLAINING THE RATIOS OF MASSES OF ALL THREE GENERATIONS
OF LEPTONS AND QUARKS AND PREDICTING THE MASS EIGENSTATES
OF NEUTRINOS

Nikola Perkovica

a
Institute of Physics and Mathematics, Faculty of Science, University of
Novi Sad, Dositej Obradovic square 3, Novi Sad, 21000, Serbia

[email protected]

In this paper we will provide a new equation that explains why there are three generations or families of leptons and
quarks, respectively. We will also explain why all those particles have the known mass ratios amongst their three
respective generations and flavors. We will also tackle the problem of Yukawa couplings being arbitrary parameters in
the Standard Model Higgs mechanism, which is a long standing problem do to their formulaic dependence on the
Higgs Vacuum Expectation Value (VEV). We will attempt to solve this problem and provide a strong argument
through an equation for Yukawa couplings of all leptons and quarks via a new methodology that depends on the
running of the fine-structure constant on the Q scale, quantum numbers and the Weinberg angle (also on the Q scale).
We will also make predictions for all three left-chiral neutrino mass eigenstates and we will provide upper limits for
the three right-chiral neutrino mass eigenstates.

Keywords: Higgs Mechanism, Yukawa Coupling, Fine structure constant, Leptons, Quarks

PACS Nos: 12.15.Ff, 12.15.Hh, 12.15.Lk

1. Introduction

In the Standard Model of Particle Physics [1. 2, 3, 4], electroweak symmetry breaking [5, 6, 7, 8] is
responsible for the mass generation of W and Z gauge bosons thus rendering the weak interactions
short ranged. The Standard Model scalar potential is:

V(Φ) = m2 Φ † Φ + λ(Φ† Φ)2 (1)

where the Higgs field Φ is a self-interacting SU(2)L complex doublet that has four real degrees
of freedom, with weak hypercharge Y =1 and V(Φ) is the most general renormalizable scalar potential
and if the quadratic term is negative the neutral component of the scalar doublet acquires a non-zero
−1⁄2
vacuum expectation value 𝑣 = (√2GF) which is approximately 246,22 GeV and GF is the Fermi
coupling constant. We should also point out that:

1 √2ф+
Φ= ( 0 ) (2)
√2 ф + 𝑖𝑎 0

where ф0 and 𝑎 0 are the CP-even and CP-odd neutral components, and ф+ is the complex charged
component of the Higgs doublet, respectively. The global minimum of the theory defines the ground
state, and spontaneous symmetry breaking implies that there is a symmetry of the system that is not
respected by the ground state. From the four generators of the SU(2)𝐿 × U(1)𝑌 gauge group, three are
spontaneously broken, implying that they lead to non-trivial transformations of the ground state and
indicate the existence of three massless Goldstone bosons identified with three of the four Higgs field
degrees of freedom. The Higgs field couples to the Wμ and Bμ gauge fields associated with the
SU(2)𝐿 × U(1)𝑌 local symmetry through the covariant derivative appearing in the kinetic term of the
Higgs Lagrangian:

1
 †
ℒ Higgs = (Dμ Φ) (Dμ Φ) − V(Φ) (3)

Where the covariant derivative equals:

𝑖gσ𝑎 Wμ𝑎 𝑖g′YBμ
Dμ = ∂ μ + + (4)
2 2

g and g′ are the SU(2) and U(1) gauge couplings, respectively, and σ𝑎 where 𝑎 = 1, 2, 3are the typical
Pauli matrices. As a result, the neutral and the two charged massless Goldstone degrees of freedom
mix with the gauge fields corresponding to the broken generators of SU(2)𝐿 × U(1)𝑌 and become the
longitudinal components of the Z and W gauge bosons, respectively. The Z and W gauge bosons
acquire masses MW = g𝑣⁄2 and MZ = (g ′ + g)𝑣⁄2. The fourth generator remains unbroken since it is
the one associated to the conserved U(1)QED gauge symmetry therefore its corresponding gauge field
remains massless or in other words, the photon is massless. Similarly the eight color gauge bosons, the
gluons, corresponding to the conserved SU(3)𝐶 gauge symmetry with eight unbroken generators, also
remain massless. Therefore, from the initial four degrees of freedom of the Higgs field, two are
absorbed by the W ± gauge bosons, one by the Z 0 gauge boson, and there is one remaining degree of
freedom H, that is the physical Higgs boson. The Higgs boson is neutral under the electromagnetic
interactions and transforms as a singlet under SU(3)𝐶 and hence does not couple at tree level to the
massless photons and gluons. The mass of the Higgs boson is given as mh = √2λ𝑣 2 , where λ is a
free coupling parameter and therefore the mass of the Higgs boson is not predicted in the Standard
Model. With the Higgs field in the unitary gauge, the SU(2)𝐿 × U(1)𝑌 invariant Yukawa Lagrangian
For leptons takes the form:

λ𝑓 𝑣 λ𝑓 ℎ
̅ ΦeR + Φ † e̅R L) = −
ℒ𝑓 = −λ𝑓 (L e̅e − e̅e (5)
√2 √2

The respective masses of fermions are not predicted since the Yukawa coupling λ𝑓 is a free parameter
provided in the formula:

λ𝑓 𝑣
M𝑓 = (6)
√2

in that sense the Higgs mechanism does not predict any of the elementary fermion masses. It is
possible to estimate the strength of the fermion-fermion-Higgs interactions:

Me Mu
ℒ𝑓𝑓ℎ = e̅eℎ − u
̅ uℎ + ⋯ (7)
𝑣 𝑣

where Me is the mass of an electron and Mu is the mass of an up quark. A very important consequence
of the fermion-fermion-Higgs interaction is its direct dependence on fermion masses. The larger the
mass the stronger this interaction becomes. In order to make sure that Yukawa couplings are no longer
arbitrary parameters in the SM Higgs mechanism, we have to avoid using the Higgs VEV to calculate
the Yukawa couplings.

2
 2. The Higgs-Yukawa family/generation equation

We will introduce a new equation for Yukawa couplings. This new equation doesn’t depend on the
Higgs VEV and it answers why mass ratios of the three generations or families are as such. The
equation is:

1−nY 1−c3
[(−S) w ∙ ng ]
2 c
1
sin θ (Q)
[ng + ( n W ∙ N ∙ k п
)] α(Q)
𝑓∙π
λ𝑓 = ∫ x Ndx ∙ N c4 (8)
(1 + ∆q𝑓 )c2 0

( )

where α(Q) is the running value of the fine structure constant on the scale Q, N is the generation or
family number for the first, second and third generations respectively, θW (Q) is the running value of
the Weinberg angle and (1 + ∆q𝑓 ) = (1 + ∆q)−1 for unstable leptons, where ∆q encapsulates the
higher order QED corrections and can be expressed as a power series expansion in the renormalized
electromagnetic coupling constant α where ∆q = ∑∞ j
i=0 ∆q in which the index j gives the power of α
j
that appears in ∆q but this value can also be experimentally measured by calculating it from the mean
lifetimes of unstable leptons or quarks (where we have to include the CKM matrix as well):

G2F ∙ M𝑓5
τ𝑓−1 = ∙ (1 + ∆q) (9)
192π3
where τ𝑓 is the mean lifetime on the unstable fermion. We’re using natural units so the reduced Planck
constant has been removed from the equation. All unstable particles have different values of ∆q.

Further on 𝑓 = 𝑙, 𝑞 is the fermion flavor, 𝑙, 𝑞 are lepton and quark flavors, respectively. The quantum
number ng ≡ 3 is the number of generations or families, n𝑓 ≡ 6 is the number of flavors since both
leptons and quarks have six flavors each, S = 1/2 is the fermion spin quantum number, nYw is the
number of particles that interact via the weak hypercharge, where Yw = 2 ∙ (Qe − T3 ) is the weak
hypercharge, Qe is the (electric) charge quantum number and T3 is the third component of the weak
isospin. The quantum number nYw is defined by the equation:

2 2 )+α (Q)
Qe (2∙T3 ⁄S G
nYw = [(2 ∙ T3 − Qe ) + Yw ∙ ] (10)
(B − L)

where B is the baryon quantum number, L is the lepton quantum number and αG (Q) is the
gravitational coupling on the scale Q. Because the gravitational coupling has a tiny value for most
particles (around 10−39), we will therefore approximate its value to zero for all quarks and leptons
except for the right-handed (or right-chiral) neutrinos, in their case αG (Q) will have a non-zero value.
The quantum number п = nup + nup̅ is the number of unstable particles nup and unstable anti-
particles nup̅ , whereas k equals:

(N + 1)Ψ
k= (11)
nf

3
and Ψ = 3.3598856 … is the reciprocal Fibonacci constant. The parameters c1 , c2 , c3 and c4 are
defined as:

2
Qe (Q𝑓 + L𝑓 )
c1 = − [ − I3 ] (12)
S ∙ (B − L)

Where Q𝑓 and L𝑓 are quark and lepton flavor quantum numbers, respectively and I3 is the third
component of isospin. Then:

Qe 2
c2 = [ ∙ S [Qe+(B+L)] ] (13)
(B − L)

then:

Q2e 2
c3 = ∙ N ∙ S 2∙[Qe +(B+L)]
(B − L)2 (14)

then:

Qe 2
c4 = 2 ∙ ∙ S [Qe+(B+L)]
(B − L) (15)

After solving the integral we get:

1−nY 1−c3
[(−S) w ∙ ng ]
2 c1
sin θW (Q)
αN+1 (Q) ∙ [ng + ( п
n𝑓 ∙ π ∙ N ∙ k )]
λ𝑓 = ∙ N c4 (16)
(N + 1) ∙ (1 + ∆q𝑓 )c2
( )

3. Leptonic solutions

All leptons have a lepton quantum number L = 1 and all of their respective anti-particles have a
lepton quantum number L = −1. All left-chiral leptons have a weak hypercharge Yw = −1 whereas
right-chiral charged leptons have a weak hypercharge Yw = −2 and (if they exist) right-chiral
neutrinos don’t have a weak hypercharge, weak isospin or (electric) charge, therefore making them
“sterile”.

4
 3.1 Charged leptons

All charged leptons, regardless of chirality, have a charge quantum number Qe = −1 and the opposite
is true for their anti-particles. Left-chiral charged leptons have a weak isospin T3 = − 1⁄2 and their
right-handed equivalents have a zero weak isospin.

When N = 1 and therefore 𝑓 = 𝑒, α(Q) = α where α is the fine structure constant, L𝑓 = L𝑒 = 1 where
L𝑒 is the electron lepton quantum number, we obtain the formula for the electron Yukawa coupling:

−2
sin2 θW (M𝑒 )
α2 ∙ [3 + ( 6π )]
λ𝑒 = (17)
2

All the values for all three generations/families and flavors of charged leptons are provided in table
(1) and table (2) respectively.

When N = 2 and therefore 𝑓 = 𝜇, L𝑓 = L𝜇 = 1 we obtain the formula for the muon Yukawa
coupling:

−2 1⁄3
3
sin2 θW (M𝜇 )
α (M𝜇 ) ∙ [3 + ( ∙ Ψ)]
6π
λ𝜇 = ⁄4 (18)
3 ∙ (1 + ∆q𝜇 )
( )
where α(M𝜇 ) is the value of the fine structure constant on the muonic scale, that is when Q = M𝜇. We
̅̅̅̅ renormalization scheme to calculate the so called running of the fine-structure
will use the MS
constant on the muonic scale. The effective value of the fine structure constant is obtained by using
the equation :

α
α(Q) = (19)
̂ (Q)
1−Π

where Π̂ (Q) is the photon vacuum polarization function which can be written as Π ̂ (Q) = ∑∞ ̂𝑖
𝑖=1 Π (Q)
̅̅̅̅ renormalization scheme
where each term receives contributions from all fermion flavors. In the MS
the counter terms are chosen so that they only contain divergent pieces with the addition of certain
constants. One-loop counter terms are proportional to ∆= 1⁄ε − 𝛾E + ln(4π) + 𝑂(ε) where 𝛾E is the
Euler-Mascheroni constant. An appropriate choice for the ’t Hooft mass is 𝜇 = m𝜇 and therefore we
write α(Q) = α(M𝜇 ). Ultimately we get the equation:

α α2 m𝜇2
α(M𝜇 ) = + 𝑙𝑛 ( ) (20)
α m2 4π2 m2𝑒
1 − 3π ln ( 𝜇2 )
m𝑒

The calculated value is provided in table (1). We will not repeat the calculation processes for every
individual particle, in future reference we will simply provide the results in respective tables so the
paper wouldn’t be unnecessarily long.

5
The (1 + ∆q𝜇 ) corrections for muons are:

−1
m𝑒 α 25
(1 + ∆q𝜇 ) = {𝑓𝑠 ( ) [1 + 2 ( − π2 )]} (21)
m𝜇 4π 4

where 𝑓𝑠 denotes the phase space factor for one massive particle in the final state. The phase space
factor is almost negligible for the muon decay 𝑓(m𝑒 ⁄m𝜇 ) = 0.999813(16). The value (1 + ∆q𝜇 ) is
also provided in table (1), however it can also be measured experimentally from the muon mean
lifetime. This, in fact, applies for all unstable leptons and quarks. It’s interesting that there are only
two unstable leptons and only two stable quarks.

When N = 3 and therefore 𝑓 = 𝜏, , L𝑓 = L𝜏 = 1 we obtain the formula for the tau lepton Yukawa
coupling:

1⁄9
−2
sin2 θW(M𝜏 )
α4 (M𝜏 ) ∙ [3 + ( ∙ Ψ)]
3π
λ𝜏 = ⁄9 (22)
4 ∙ (1 + ∆q𝜏 )
( )

With the values listed in the two tables below.

𝑓 α−1 (Q) (1 + ∆q𝑓 ) sin2 θW (Q)
𝑒 137.035999084(21) 1 0.224785(14)
𝜇 135.9001(04) 1.00440414(26) 0.226298(25)
𝜏 133.557(43) 0.17789(22) 0.2264(24)
Table (𝟏) – The calculated vales of charged lepton parameters with the exception of α where we used
the experimental value, as provided by NIST.

N λN MN [MeV ∙ c−2 ]
−6
1 2.93503(18) ∙ 10 0. 51099895000(15)
−4
2 6.0687(20) ∙ 10 105.6583755(23)
3 0.01021(24) 1776.86(12)
Table (𝟐) – The calculated values of Yukawa couplings of the first, second and third generations of
charged leptons and the experimental values of their respective masses as provided by NIST.

3.2 Neutrinos

If neutrinos are Dirac fermions, the equation can calculate their Yukawa couplings and masses. All
neutrinos have a charge quantum number Qe = 0. Left-chiral neutrinos have a weak isospin T3 = 1⁄2
and their right-handed equivalents (if they exist) have a zero weak isospin. Neutrinos have the same
lepton flavor numbers as their charged equivalents, corresponding to electron, muon and tay neutrinos.

6
 3.2.1 Left-chiral neutrinos

Because they don’t have charge, neutrino mass eigenstates are easy to calculate and therefore we can,
and will, predict their respective masses. Because of the nature of QED, the value of α(Q) cannot be
lower than the value of the fine structure constant α. Therefore, even though all three neutrino flavors
𝑣𝑒 , 𝑣𝜇 and 𝑣𝜏 have much smaller masses than electrons, we have to use the value of α in the neutrino
equation:

3
αN+1
λ𝑣𝑓 =( ) (23)
𝐿 (N + 1)

This means that neutrino masses depend exclusively on their respective generation/family number N.
We get the results listed in table (3) below.

N λN MN [eV ∙ c−2 ]
−14
1 1.89(28) ∙ 10 3.29(18) ∙ 10−3
−21
2 2.24(32) ∙ 10 3.80(30) ∙ 10−10
−28
3 3.61(35) ∙ 10 6.20(40) ∙ 10−17
Table (𝟑) – The calculated values of left-handed neutrino Yukawa couplings and mass eigenstates.

Because neutrino oscillations have been proven to exist [11, 12], we know that neutrinos have masses
albeit tiny ones. The current experimental upper limit for the sum of all three neutrino mass
eigenstates is 0.09 eV ∙ c−2 , which is in great agreement with the neutrino predictions in the table
above. As we can see, left-chiral or left-handed neutrinos have an “inverse” mass hierarchy as
opposed to the charged lepton that have a normal mass hierarchy. The equation doesn’t predict
nor necessitate the existence of anti-neutrinos but if they exist, the equation can accommodate their
existence and predict that they have the same Yukawa couplings and masses as neutrinos.

3.2.2 Right-chiral neutrinos

If the right-chiral or right-handed neutrinos do exist (the equation doesn’t necessitate their existence)
then they have to be sterile. Because of their colossal mass, αG (Q) has a non-zero mass. We don’t
have to calculate αG (Q), we only need to know that it isn’t equal to zero or very close to zero as is the
case will all other leptons and even the most massive quarks. Because they’re sterile, right-handed
neutrinos don’t have a weak hypercharge, so nYw = 0, they don’t have a weak isospin and of course
they don’t have an electric charge either. Therefore the equation is:

3
−
αN+1 (Q) 2
λ𝑣𝑓 =( ) (24)
𝑅 (N + 1)

The effective or “running” values of α are very difficult to calculate on such colossal mass scales so
we will ignore it and use the values of the fine-structure constant instead. This obviously won’t give
us the exact predictions of right-handed neutrino Yukawa couplings and masses but due to the nature

7
of the equation above, it will give use the “upper most limits” because the higher the values of α(Q)
are, the smaller the Yukawa couplings and masses of right-handed neutrinos are, which is unique for
them, evidently the opposite is true for all other particles, even left-handed neutrinos.

N λN MN [GeV ∙ c −2 ]
1 7.28(35) ∙ 106 1.30(38) ∙ 109
10
2 2.15(37) ∙ 10 3.70(43) ∙ 1010
13
3 5.30(41) ∙ 10 9.20(50) ∙ 1015
Table (𝟑) – The calculated upper limit values of right-handed neutrino Yukawa couplings and mass
eigenstates.

These prediction make right-handed neutrinos a great “candidate” for dark matter.

4. Quark solutions

All quarks have a baryon quantum number B = 1/3 and all of their respective anti-particles have a
baryon quantum number B = −1/3. All left-chiral quarks have a weak hypercharge Yw = 1/3 and
their right-handed equivalents have Yw = 4/3 for u-type quarks and Yw = −2/3 for d-type quarks.

4.1 Down-type quark solutions

All d-type quarks have a charge quantum number Q = −1/3 and the opposite is true for their anti-
particles Q = 1/3. Left-handed d-type quarks have a weak isospin T3 = − 1⁄2 whereas their right-
handed equivalents don’t have a weak isospin meaning that the value is zero.

When N = 1 and therefore 𝑓 = 𝑑, Q𝑓 = I3 = −1/2 the formula for down quarks is λ𝑑 = α2 ⁄2 where
we used α(m𝑑 ) ≅ α for the sake of simplicity. Having in mind that the down quark is not a whole lot
more massive than the electron, we can safely ignore the running of the fine structure constant without
sacrificing any relevant accuracy.

When N = 2, therefore 𝑓 = 𝑠 and Q𝑓 = S′ = −1 where S′ is the strangeness quantum number, the
formula for strange quarks is:

1⁄3
2
3 (M sin2 θW (M𝑠)
α 𝑠 ) ∙ [3 + ( 6π ∙ Ψ)]
λ𝑠 = ⁄4 (25)
3 ∙ (1 + ∆q𝑠 )−1
( )
When N = 3 and therefore 𝑞 = 𝑏, Q𝑓 = B′ = −1 where B′ is the bottomness quark quantum number,
the formula for the bottom quarks is:

8
 1⁄9
2
sin2 θW(M𝑏 )
α4 (M𝑏 ) ∙ [3 + ( 3π ∙ Ψ)]
λ𝑏 = ⁄9 (26)
4 ∙ (1 + ∆q𝑏 )−1
( )

where (1 + ∆q𝑏 ) = ( |𝑉𝑐𝑏 |2 (1 + ∆q))−1 , ∆q is obtained from the bottom quark mean lifetime and
|𝑉𝑐𝑏 | is a CKM matrix parameter. The values of CKM parameters and the coefficients are known from
experimental results [16, 17]. We won’t repeat these calculations for other quarks and their respective
CKM matrix parameters in order to avoid repeatability.

𝑓 α−1 (Q) (1 + ∆q𝑓 ) sin2 θW (Q)
𝑑 ≈ α−1 1 ≈ sin2 θW (M𝑒 )
𝑠 ≈ 136 0.004(14) ≈ sin2 θW (M𝜇 )
𝑏 ≈ 132 58(22) 0.227(11)
Table (𝟒) – The calculated vales of d-type quark parameters with the exception of α where we used
the experimental value, as provided by NIST.

N λN MN [MeV ∙ c−2 ]
−5
1 2.66257(25) × 10 4.636(18)
2 5.434(42) × 10−4 96(05)
3 2.47(44) × 10−2 4200(92)
Table (𝟓) – The calculated values of d-type quark Yukawa couplings and masses.

4.2 Up-type quarks

All u-type quarks have a charge quantum number Q = 2/3 and the opposite is true for their anti-
particles Q = −2/3. Left-handed d-type quarks have a weak isospin T3 = 1⁄2 whereas their right-
handed equivalents don’t have a weak isospin meaning that the value is zero.

When N = 1 and therefore 𝑓 = 𝑢, Q𝑓 = I3 = 1/2 the formula for up quarks is:

1
−
2 sin2 θW (M𝑢) 2
α ∙ [3 + ( 6π )]
(27)
λ𝑢 =
2

where we used α(m𝑢) ≅ α as we did with the down quarks, we also estimated that the Weinberg
angle is very similar for up quarks as it is for electrons.

9
When N = 2, therefore 𝑓 = 𝑐 and Q𝑓 = C = 1 where C is the charmness quantum number, the
formula for charm quarks is:

1⁄3
−4
sin2 θW(M𝑐 )
α3 (M𝑐 ) ∙ [3 + ( ∙ Ψ)]
6π
λ𝑐 = ∙4 (28)
3 ∙ (1 + ∆q𝑐 )
( )
When N = 3 and therefore 𝑞 = 𝑡, Q𝑓 = T = 1 where T is the topness quark quantum number, the
formula for the top quarks is:

1⁄9
−4
4 sin2 θW (M𝑡 )
α (M𝑡 ) ∙ [3 + ( 3π ∙ Ψ)]
λ𝑡 = ∙9 (29)
4 ∙ (1 + ∆q𝑡 )
( )

𝑓 α−1 (Q) (1 + ∆q𝑓 ) sin2 θW (Q)
−1
𝑢 ≈α 1 ≈ sin2 θW (M𝑒 )
𝑐 ≈ 134 0.28(16) ≈ sin2 θW (M𝜏 )
𝑡 ≈ 127 0.005(27) 0.2312(22)
Table (𝟔) – The calculated vales of u-type quark parameters with the exception of α where we used
the experimental value, as provided by NIST.

N λN MN [GeV ∙ c−2 ]
−5
1 1.54(17) × 10 2.674(21) × 10−3
−3
2 7.32(35) × 10 1.26(06)
3 0.991(14) 173(09)
Table (𝟕) – The calculated values of u-type quark Yukawa couplings and masses.

5. Conclusions & Debate

We managed to explain why there are three generations of particles, both for leptons and quarks
respectively. We also explained why the three generations have such mass ratios. We also found a
way to measure the Weinberg angle on low energy levels of charged leptons and lighter quarks. We
also explained why up and down quarks have the masses that they do, which was previously
explained. Our equation doesn’t treat particle masses as constants which was a problem with the
Koide formula. We also managed to predict the mass eigenstates of all three left-handed
neutrinos and we even made predictions for the upper limits of right-handed sterile neutrinos. There is
also a possibility to use this new equation in a U(1)B−L symmetry, or perhaps similar B − L GUT
symmetries.

10
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