6.5. FIELD THEORY OF MULTI-PARTICLE SYSTEMS 391
Thus, we have two kinds of classifications (6.5.55) and (6.5.56) of sub-systems for atomic
orbital electrons, which lead to two different sets of field equations.
A. FIELD EQUATION OF SYSTEMSn. If we ignore the orbit-orbit interactions, then we
take (6.5.55) as anN-particle system. LetSnhaveKnelectrons:
(6.5.57) Sn:Ψn= (ψn^1 ,···,ψnKn), Kn≤Nn, 1 ≤n≤N,
whereNnis as in (6.5.54). Hence, the model of (6.5.57) is reduced to theSU(K 1 )× ··· ×
SU(KN)gauge fields of fermions. Referring to the single fermion system (6.5.15)-(6.5.21),
the action of (6.5.57) is
(6.5.58) L=
∫ N
∑
n= 1(LSU(Kn)+LDn)dx,where
(6.5.59)
LSU(Kn)=−1
4 hc ̄gμ αgν βAaμ νnAaα βn 1 ≤an≤Kn,LDn=Ψn(iγμDμ−
mec
h ̄)Ψn 1 ≤n≤N,Aaμ νn =∂μAaνn−∂νAaμn−e
̄hcλbanncnAbμnAcνn,DμΨn= (∂μ−ie
hc ̄A^0 μ−ie
hc ̄Aaμnτan)Ψn,whereAaμnare theSU(Kn)gauge fields representing the electromagnetic(EM)potential of
the electrons inSn,λbanncnare the structure constants ofSU(Kn)such thatGanbn=^12 tr(τanτb†n) =
δanbn,A^0 μis theEMpotential generated by the nuclear,g=−e(e> 0 )is the charge of an
electron, andmeis the electron mass.
The PID gradient operators forSU(K 1 )× ··· ×SU(KN)in (6.5.19) are given by
(6.5.60) Dnμ=
1
̄hc[
∂μ+
e
hc ̄ k∑ 6 =nA(μk)]
for 1≤n≤N,whereA
(k)
μ =α
Kk
aKAak
μ is the total EM potential ofSkshell as defined in (6.5.10).
Then by (6.5.58)-(6.5.60), the field equations of (6.5.57) can be written in the following
form
∂νAaν μn+e
hc ̄(6.5.61) λbanncngα βAbα μnAcβn+eΨγμτanΨn
=
[
∂μ+e
hc ̄ k∑ 6 =nA(μk)]
φan for 1≤an≤Kn^2 − 1 , 1 ≤n≤N,iγμ[
∂μ−ie
hc ̄
A^0 μ−ie
hc ̄
Aaμnτan]
Ψn−mec
̄h(6.5.62) Ψn= 0.