On the thermodynamical analogy in spin-polarized density functional theory

Abstract

The thermodynamical analogy of density functional theory, which is an organic part of the spin-independent version of the theory, is reconsidered for its spin-polarized generalization in view of the recently uncovered nonuniqueness of the external magnetic field B(r) corresponding to a given pair of density n(r) and spin density ns(r). For ground states, the nonuniqueness of B(r) implies the nondifferentiability of the energy functional E[n,ns] with respect to ns(r). It is shown, on the other hand, that this nonuniqueness allows the existence of the one-sided derivatives of E[n,ns] with respect to ns(r). Although the N-electron ground state can always be obtained from the minimization of E[n,ns] without any constraint on the spin number Ns, the Lagrange multiplier mus associated with the fixation of Ns does not vanish even for ground states. Rather, mus is identified as the left- or right-side derivative of the total energy with respect to Ns. This justifies the interpretation of mus as a (spin) chemical potential, which is the cornerstone of the thermodynamical analogy.