200 CHAPTER 4. UNIFIED FIELD THEORY
Let
J=
c
4 πcurl^2 A, Js=e^2 s
msc|ψ|^2 A−ihe ̄ s
ms(ψ∗∇ψ−ψ∇ψ∗).Physically,Jis the total current inΩ, andJsis the superconducting current. SinceΩis a
medium conductor,Jcontains two types of currents as
J=Js+σE,whereσis dielectric constant,σEis the current generated by the electric fieldE,
E=−
1
c∂A
∂t−∇Φ=−∇Φ,
andΦis the electric potential. SinceAt=0, the superconducting current equations should be
taken as
(4.2.38)
1
4 πcurl^2 A=−σ
c∇Φ−
e^2 s
msc^2|ψ|^2 A−i ̄hes
msc(ψ∗∇ψ−ψ∇ψ∗).Since (4.2.37) is the expression of (4.2.36), then the equation (4.2.38) can be written in
the abstract form
(4.2.39)
δG
δA=−
σ
c∇Φ.
In addition, for conductivity, the gauge fixing is given by
divA= 0 , A·n|∂Ω= 0 ,which imply that ∫
Ω∇Φ·Adx= 0.Hence, the term−σc∇Φin (4.2.39) can not be added into the Ginzburg-Landau free energy
(4.2.35).
However, the equation (4.2.39) are just the variational equation with divergence-free con-
straint as follows
〈δG
δA,X〉=
d
dλG(A+λX)|λ= 0 = 0 ∀divX= 0.Thus, we see that the Ginzburg-Landau superconductivity theory obeys PID.
4.3 Unified Field Model Based on PID and PRI
4.3.1 Unified field equations based on PID
The abstract unified field equations (4.1.33)-(4.1.34) are derived based on PID. We now
present the detailed form of this model, ensuring that thesefield equations satisfy both the
principle of gauge-symmetry breaking, Principle4.4, and PRI.