Physical Foundations of Cosmology

162 The very early universe

respectively,wherei= 1 , 2 ,3 is the generation index. The lower components are
linear superpositions of the appropriate flavors,

d′i=Vjidj, (4.81)

whereVij is the unitary 3× 3 Kobayashi–Maskawa matrix. The general quark
Yukawa term can then be written as

LqY=−fijdχQ ̄iLφ 0 dR′j−fijuχQ ̄iLφ 1 uRj+h.c., (4.82)

where

QiL=

(

ui

d′i

)

, φ 1 =

(

1

0

)

. (4.83)

The second term on the right hand side in (4.82) is also gauge-invariant and generates
the masses of the upper components of the doublets. Expression (4.82), rewritten
in terms of the original flavors, gives the mass term

Lmq=−

(

Vmi∗fijdVkj

)

χd ̄LmdRk−fijuχu ̄iLujR+h.c. (4.84)

Taking the matricesfijdandfijusuch that
(
Vmi∗fijdVkj

)

χ 0 =mdkδmk (4.85)

and

fijuχ 0 =muiδij, (4.86)

we get the usual quark mass terms. The Yukawa coupling constant is largest for the
top quark,ft 0 .7(mt170 GeV).For the other quarks it is more than 10 times
smaller.
Neutrino masses, which – according to measurements – are different from zero,
can be generated in an almost identical manner. In this case, the neutrino flavors
naturally mix in a similar way to the quark generations and this leads to neutrino
oscillations.

4.3.6 CP violation

The parity operationPcorresponds to reflection(t,x,y,z)→(t,−x,−y,−z)and
converts left-handed particles into right-handed particles without changing their
other properties. Charge conjugationCreplaces particles by antiparticles without
changing handedness. For instance, theCoperation converts a left-handed electron
to a left-handed positron. Any chiral gauge theory is not invariant with respect to