of second order phase transitions,GinzburgandLandausuggested that the free energyFSin the
superconducting state can be written in the following form
FS=FN−α|φ|^2 +
β
2|φ|^4 +1
2 m∣∣
∣(−i~∇−qA)φ∣∣
∣2
+1
2 μ 0Ba^2 , (287)whereα andβ are phenomenological constants and mis the quasiparticle’s mass. Further, FN
denotes the free energy of the normal state. The equation can be interpreted in the following way:
α|φ|^2 +β 2 |φ|^4 is a term of the typical form appearing inLandau’s theory of second order phase
transitions, 21 m
∣∣
∣(−i~∇−qA)φ∣∣
∣2
is an additional term which accounts for energy corrections dueto spatial variations of the order parameterφand the last term, 2 μ^10 Ba^2 represents an additional
contribution to the free energy according to Eq. (271). Minimizing the free energyFSwith respectφ
yields theGinzburg - Landauequations in terms of functional derivatives:
δFS=δFS
δφ
δφ+δFS
δφ∗
δφ∗. (288)Note that|φ|=φφ∗. We obtain
δFS =[
−αφ+β|φ|^2 φ+1
2 m(−i~∇−qA)φ·(i~∇−qA)]
δφ∗+h.c.= 0. (289)In the kinetic term of the right hand side we have to deal with a term of the form∇φ·∇δφ∗. We
note that
∫
dr∇φ·∇δφ∗=−∫
dr(∇^2 φ)δφ∗, where we assumed thatδφ∗vanishes at the integration
boundaries. Conclusively we obtain
∫
drδFS=
∫
dr[
−αφ+β|φ|^2 φ+1
2 m(−i~∇−qA)^2 φ]
δφ∗+h.c. (290)This is expression is equal to zero if
−αφ+β|φ|^2 φ+1
2 m
(−i~∇−qA)^2 φ= 0. (291)This is the firstGinzburg - Landauequation. In order to obtain the secondGinzburg - Landau
equation, one minimizesFS, Eq. (287), with respect to the vector potentialA.
δFS
δA=
q
2 m
[φ(−i~∇+qA)φ∗−φ∗(−i~∇−qA)φ] +1
μ 0∇×∇×A, (292)
where we employed some rules of functional derivatives in the sense of distributions. In particular, we
first define the functionalBa(r) =F[A] =
∫
dr′[∇×A(r′)]^2 δ(r−r′). We now write
〈
δF[A]
δA,f〉
=
d
dεF[A+εf]∣∣
∣
ε=0
= 2∫
dr′(∇×f)·(∇×A)δ(r−r′)= 2∫
dr′f·∇×∇×Aδ(r−r′). (293)