240 CHAPTER 4. UNIFIED FIELD THEORY
The weak force between the two particles is given by(4.6.33) F=−
d
drV=gw(ρ 1 )gw(ρ 2 )e−kr[
1
r^2+
k
r−
4 B
ρk^2 re−kr]
.
3.Repulsive condition. For the two particles as above, if their weak interaction constant
Bsatisfies the inequality
1
r^2+
k
r≥
4 B
ρk^2 re−kr, ∀ 0 <r≤1
k,
or equivalentlyBsatisfies
(4.6.34) B≤
e
2ρk (e= 2. 718 ,k= 1016 cm−^1 ),then the weak force between these two particles is always repulsive.
It follows from this conclusion that for the neutrinos:
(ν 1 ,ν 2 ,ν 3 ) = (νe,νμ,ντ),
(ν 1 ,ν 2 ,ν 3 ) = (νe,νμ,ντ),the weak interaction constants
Bijforνiandνj ∀ 1 ≤i,j≤ 3 ,
Bijforνiand anti-neutrinosνj ∀i 6 =j,satisfy the exclusion condition (4.6.34).
4.Value of weak charge gw. Based on the Standard Model, the coupling constantGwof
theβ-decay of nucleons and the Fermi constantGfhave the following relation
(4.6.35) G^2 w=
8
√
2
(m
Wc
h ̄) 2
Gf,andGfis given by
(4.6.36) Gf= 10 −^5 ̄hc/
(mpc
h ̄) 2
,
wheremWandmpare masses ofW±bosons and protons. By the gauge theory,Gwis also the
coupling constant ofSU( 2 )gauge fields. Therefore we can regardGwas the weak charge of
nucleons, i.e.
Gw=gw(ρn), ρn the nucleon radius.
In addition, it is known that
gw(ρn) = 9(
ρw
ρn) 3
gs.