Standard Model (mathematical formulation)

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For a basic description, see the article on the Standard Model.

This is a detailed description of the standard model (SM) of particle physics. It describes how the leptons, quarks, gauge bosons and the Higgs particle fit together. It gives an outline of the main physics that the theory describes, and new directions in which it is moving.

It might be helpful to read this article along with the companion overview of the standard model.

A chiral gauge theory

This article uses the Dirac basis instead of the more appropriate Weyl basis for describing spinors. The Weyl basis is more convenient because there is no natural correspondence between the left handed and right handed fermion fields other than that generated dynamically through the Yukawa couplings after the Higgs field has acquired a vacuum expectation value (VEV).

The helicity projections of a Dirac field ψ are

left helicity:

psi_L = frac{1}{2}(1-gamma_5)psi

and the right helicity:

psi_R = frac{1}{2}(1+gamma_5)psi

are needed, because the SM is a chiral gauge theory, ie, the two helicities are treated differently.

Right handed singlets, left handed doublets

Under the weak isospin SU(2) the left handed and right handed helicities have different charges. The left handed particles are weak-isospin doublets (2), whereas the right handed are singlets (1). The right handed neutrino does not exist in the standard model. (However, in some extensions of the standard model they do) The up-type quarks are charge 2/3 quarks: u, c, t. The charge -1/3 quarks (d, s, b) are called down-type quarks. The theory contains

the left handed doublet of quarks

Q_L= (u_L, d_L)

and leptons

E_L= (nu_L, e_L)

the right handed singlets of quarks

u_R

and

d_R

and the electron

e_R

There is no right-handed neutrino in the SM. This is essentially by definition. When the Standard Model was written down, there was no evidence for neutrino mass. Now, however, a series of experiments including Super-Kamiokande have indicated that neutrinos indeed have a tiny mass. This fact can be simply accommodated in the Standard Model by adding a right-handed neutrino. This, however, is not strictly necessary. For example, the dimension 5 operator

frac{(Hl)^2}{Lambda}

also leads to neutrino oscillations.

This pattern is replicated in the next generations. We introduce a generation label $i=1,2,3$ and write $u_i$ to denote the three generations of up-type quarks, and similarly for the down type quarks. The left handed quark doublet also carries a generation index, $Q_{iL}$ , as does the lepton doublet, $E_{iL}$ .

Why this?

What dictates this form of the weak isospin charges? The coupling of a right handed neutrino to matter in weak interactions was ruled out by experiment long ago. Benjamin Lee and J. Zinn-Justin, and Gerardus 't Hooft and Martinus Veltman in 1972 suggested the inclusion of left and right handed fields into the same multiplet. This possibility has been ruled out by experiment. This leaves the construction given above.

For the leptons, the gauge group can then be $SU(2)_l times U(1)_L times U(1)_R$ . The two U(1) factors can be combined into $U(1)_Y times U(1)_l$ where $l$ is the lepton number. Gauging of the lepton number is ruled out by experiment, leaving only the possible gauge group $SU(2)_L times U(1)_Y$ . A similar argument in the quark sector also gives the same result for the electroweak theory. This form of the theory developed from a suggestion by Sheldon Glashow in 1961 and extended independently by Steven Weinberg and Abdus Salam in 1967 (and in rudimentary form by Julian Schwinger in 1957).

The gauge field part

The gauge group has already been described. Now one needs the fields. The non-Abelian gauge field strength tensor

F^a_{ munu}=partial_{mu}A^{a}_{ nu} - partial_{nu}A^{a}_{ mu} + g f^{abc}A^{b}_{mu}A^{c}_{nu}

in terms of the gauge field

A^{a}_{mu}

, where the subscript

mu

runs over spacetime dimensions (0 to 3) and the superscript

a

over the elements of the adjoint representation of the gauge group, and

g

is the gauge coupling constant. The quantity

f^{abc}

is the structure constant of the gauge group, defined by the commutator

[t_{a}, t_{b}] = f^{abc} t_{c}

. In an Abelian group, since the generators

t_{a}

all commute with each other, the structure constants vanish, and the field tensor takes its usual Abelian form.

We need to introduce three gauge fields corresponding to each of the subgroups $SU(3) times SU(2) times U(1)$ —

The gluon field tensor will be denoted by $G^{a}_{munu}$ , where the index $a$ labels elements of the 8 representation of colour SU(3). The strong coupling constant will be labelled $g_{s}$ or $g$ , the former where there is any ambiguity. The observations leading to the discovery of this part of the SM is discussed in the article in quantum chromodynamics.
The notation $W^{a}_{munu}$ will be used for the gauge field tensor of SU(2) where a runs over the 3 of this group. The coupling will always be denoted by $g$ . The gauge field will be denoted by $W^{a}_{mu}$ .
The gauge field tensor for the U(1) of weak hypercharge will be denoted by $B_{munu}$ , the coupling by $g'$ , and the gauge field by $B_{mu}$ .

The gauge field Lagrangian

The gauge part of the electroweak Lagrangian is

mathcal{L}_{g} = -frac{1}{4} (W^{a}_{munu} W^{a,munu} + B_{munu}B^{munu})

The standard model Lagrangian consists of another similar term constructed using the gluon field tensor.

The W, Z and photon

The charged W bosons are the linear combinations

W^{pm}_{mu} = frac1sqrt2left(W^{1}_{mu} pm i W^{2}_{mu}right)

Z bosons (

Z_{mu}

) and photons (

A_{mu}

) are mixtures of

W^{3}

and

B

. The precise mixture is determined by the Weinberg angle

theta_W

Z_{mu}=cos theta_W W^{3}_{mu} - sin theta_W

B_{mu}, and

A_{mu} =
sin theta_W W^{3}_{mu} + cos theta_W B_{mu},

with $cos theta_W = frac g sqrt{g^{2}+g'^{2}}$

The electric charge, weak isospin and weak hypercharge are related by

Q = T^3 + Y , .

The charged and neutral current couplings

The charged currents $J^{pm}=J^{1}pm i J^{2}$ are

J^+_mu = overline U_{iL}gamma_mu D_{iL} +overline nu_{iL}gamma_mu l_{iL}.

These charged currents are precisely those which entered the Fermi theory of beta decay. The action contains the charge current piece

mathcal{L}_{CC} = frac g{sqrt2}(J_mu^+W^{-,mu}+J_mu^-W^{+,mu}).

It will be discussed later in this article that the W boson becomes massive, and for energy much less than this mass, the effective theory becomes the current-current interaction of the Fermi theory.

However, gauge invariance now requires that the component $W^{3}$ of the gauge field also be coupled to a current which lies in the triplet of SU(2). However, this mixes with the U(1), and another current in that sector is needed. These currents must be uncharged in order to conserve charge. So we require the neutral currents

J_mu^3 = frac12(overline U_{iL}gamma_mu U_{iL} - overline D_{iL}gamma_mu D_{iL} + overline nu_{iL}gamma_mu nu_{iL} - overline l_{iL}gamma_mu l_{iL})

J_mu^{em} = frac23overline U_igamma_mu U_i -frac13overline D_igamma_mu D_i - overline l_igamma_mu l_i.

The neutral current piece in the Lagrangian is then

mathcal{L}_{NC} = e J_mu^{em} A^mu + frac g{costheta_W}(J_mu^3-sin^2theta_WJ_mu^{em})Z^mu

There are no mass terms for the fermions. Everything else will come through the scalar (Higgs) sector.

Quantum chromodynamics

Leptons carry no colour charge; quarks do. Moreover, the quarks have only vector couplings to the gluons, ie, the two helicities are treated on par in this part of the standard model. So the coupling term is given by

mathcal{L}_{QCD} = overline U (partial_mu-ig_sG_mu^a T^a)gamma^mu U + overline D (partial_mu-iG_mu^a T^a)gamma^mu D.

Here T^a stands for the generators of SU(3) colour. The mass term in QCD arises from interactions in the Higgs sector.

The Higgs field

One requires masses for the W, Z, quarks and leptons. Recent experiments have also shown that the neutrino has a mass. However, the details of the mechanism that give the neutrinos a mass are not yet clear. So this article deals with the classic version of the SM (circa 1990s, when neutrino masses could be neglected with impunity).

The Yukawa terms

Giving a mass to a Dirac field requires a term in the Lagrangian which couples the left and right helicities. A complex scalar doublet (charge 2) Higgs field, $(phi^{+}, phi^{0})$ is introduced, which couples through the Yukawa interaction

mathcal{L}_{YU} = overline U_L G_u U_R phi^0 - overline D_L G_u U_R phi^- + overline U_L G_d D_R phi^+ + overline D_L G_d D_R phi^0 + hc

where

G_{u,d}

are 3×3 matrices of Yukawa couplings, with the ij term giving the coupling of the generations i and j.

Symmetry breaking

The Higgs part of the Lagrangian is

mathcal{L}_H = [(partial_mu -ig W_mu^a t^a -ig'Y_{phi} B_mu)phi]^2 + mu^2 phi^daggerphi-lambda (phi^daggerphi)^2,

where

lambda>0

and

mu^{2}>0

, so that the mechanism of spontaneous symmetry breaking can be used.

In a unitarity gauge one can set $phi^{+}=0$ and make $phi^0$ real. Then $=v$ is the non-vanishing vacuum expectation value of the Higgs field. Putting this into $mathcal{L}_{YU}$ , a mass term for the fermions is obtained, with a mass matrix $v G_{u,d}$ . From $mathcal{L}_H$ , quadratic terms in $W_{mu}$ and $B_{mu}$ arise, which give masses to the W and Z bosons

M_W = frac{v|g|}2 qquadqquad M_Z=frac{vsqrt{g^2+{g'}^2}}2.

Including neutrino mass

As mentioned earlier, in the SM classic there are no right handed neutrinos. The same mechanism as the quarks would then give masses to the electrons, but because of the missing right handed neutrino the neutrinos remain massless. Small changes can also accommodate massive neutrinos. Two approaches are possible—

Add $nu_R$ , and give a mass term as usual (this is called a Dirac mass)
Write a Majorana mass term by combining $nu_L$ with its complex conjugate

overlinenu_L^*nu_L

See seesaw mechanism.

These alternatives can easily lead beyond the SM.

The GIM mechanism and the CKM matrix

The Yukawa couplings for the quarks are not required to have any particular symmetry, so they cannot be diagonalized by unitary transformations. However, they can be diagonalized by separate unitary matrices acting on the two sides (this process is called a singular value decomposition). In other words one can find diagonal matrices

M^{2} = V_r G^{+} G V_r^{+} = V_l G G^{+} V_l^{+}.

Using these matrices, one can define linear combinations of the quark fields used till now to get a definition of the quark fields in the mass basis. These are the quark flavours of quantum chromodynamics.

On making these transformations in the neutral current, one finds no mixing of flavours, provided there is a doublet of quarks in each generation. This cancellation of flavour changing neutral currents is referred to as the Glashow-Iliopoulos-Maiani (GIM) mechanism. This mechanism was proposed before the charm quark was found, and therefore predicted this new flavour.

However, if these transformations are made in the charged current, then one finds that the current takes the form

overline U^{(m)}_Lgamma_mu VD^{(m)}_L,qquadqquad V=V_{u,l} V^+_{d,l}.

This matrix V is called the Cabibbo-Kobayashi-Maskawa (CKM) matrix. The matrix is usually not diagonal, and therefore causes mixing of the quark flavours. It also gives rise to CP-violations in the SM.

References and external links

The quantum theory of fields (vol 2), by S. Weinberg (Cambridge University Press, 1996) ISBN 0-521-55002-5.
Theory of elementary particles, by T.P. Cheng and L.F. Lee (Oxford University Press, 1982) ISBN 0-19-851961-3.
An introduction to quantum field theory, by M.E. Peskin and D.V. Schroeder (HarperCollins, 1995) ISBN 0-201-50397-2.

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