Exact factorization-based density functional theory of electrons and nuclei

Abstract

The ground state energy of a system of electrons and nuclei is proven to be a variational functional of the conditional electronic density nR(r), the nuclear wavefunction (R) and an induced vector potential Aμ(R) and quantum geometric tensor Tμ(R) derived from the conditional electronic wavefunction R(r) over nuclear configuration space, where r=r1,r2,… are electronic coordinates and R=R1,R2,… are nuclear coordinates. The ground state (nR,,Aμ,Tμ) can be calculated by solving self-consistently (i) conditional Kohn-Sham equations containing an effective potential v s(r) that depends parametrically on R, (ii) the Schr\"odinger equation for (R) and (iii) Euler-Lagrange equations that determine Tμ. The theory is applied to the E e Jahn-Teller model.