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Ginzburg–Landau equation : ウィキペディア英語版
Ginzburg–Landau theory
In physics, Ginzburg–Landau theory, named after Vitaly Lazarevich Ginzburg and Lev Landau, is a mathematical physical theory used to describe superconductivity. In its initial form, it was postulated as a phenomenological model which could describe type-I superconductors without examining their microscopic properties. Later, a version of Ginzburg–Landau theory was derived from the Bardeen-Cooper-Schrieffer microscopic theory by Lev Gor'kov, thus showing that it also appears in some limit of microscopic theory and giving microscopic interpretation of all its parameters.
==Introduction==

Based on Landau's previously-established theory of second-order phase transitions, Ginzburg and Landau argued that the free energy, ''F'', of a superconductor near the superconducting transition can be expressed in terms of a complex order parameter field, ''ψ'', which is nonzero below a phase transition into a superconducting state and is related to the density of the superconducting component, although no direct interpretation of this parameter was given in the original paper. Assuming smallness of ''|ψ|'' and smallness of its gradients, the free energy has the form of a field theory.
: F = F_n + \alpha |\psi|^2 + \frac |\psi|^4 + \frac \left| \left(-i\hbar\nabla - 2e\mathbf \right) \psi \right|^2 + \frac
where ''Fn'' is the free energy in the normal phase, ''α'' and ''β'' in the initial argument were treated as phenomenological parameters, ''m'' is an effective mass, ''e'' is the charge of an electron, A is the magnetic vector potential, and \mathbf=\nabla \times \mathbf is the magnetic field. By minimizing the free energy with respect to variations in the order parameter and the vector potential, one arrives at the Ginzburg–Landau equations
: \alpha \psi + \beta |\psi|^2 \psi + \frac \left(-i\hbar\nabla - 2e\mathbf \right)^2 \psi = 0
: \nabla \times \mathbf = \mu_\mathbf \;\; ; \;\; \mathbf = \frac \mathrm \left\
where j denotes the dissipation-less electric current density and ''Re'' the ''real part''. The first equation — which bears some similarities to the time-independent Schrödinger equation, but is principally different due to a nonlinear term — determines the order parameter, ''ψ''. The second equation then provides the superconducting current.

抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)
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