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The basic postulate in Kohn-Sham DFT is that we can apply a one-electron formulation to the system of N interacting electrons by introducing a suitable local potential VXC(r), in addition to any external potentials Vext(r) and the Coulomb potential of the electron cloud VC(r), and solving:
[ T + Vext(r) + VC(r) + VXC(r)] φi (r) = εi φi (r)
Here T is the kinetic energy operator. The potential VXC is the functional derivative with respect to the density ρ of EXC[ρ], the exchange-correlation energy functional. The one-electron molecular orbitals (MOs) φi with corresponding orbital energies εi define the exact electronic charge density and give, in principle, access to all properties because these are expressible as functional of the density, in particular the energy. Moreover, they provide an intuitively appealing view of the system as being built from independent-electron orbitals with all ensuing interpretations. The exact formof the exact energy density EXC(r), representing and incorporating all exchange and correlation (XC) effects is unknown. From general principles one can formulate conditions on what EXC(r) should look like, and several, more and more advanced expressions have been advocated for it in the literature. Their application to real systems has been impressively successful, and it seems likely that a further increase of accuracy is a matter of time.
