My question is specifically related to the molecular energies of Kohn-Sham DFT:
Do eigenvalues in KS-DFT mean anything?
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1$\begingroup$ Related: chemistry.stackexchange.com/q/128632/41556, chemistry.stackexchange.com/q/316/41556 $\endgroup$– Tyberius ♦May 16, 2020 at 13:33
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4 Answers
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This is a very interesting question and to the best of my knowledge there is not yet a conclusive answer. As the chemistry stackexchange threads linked by @Tyberius already state Kohn-Sham orbital energies and Kohn-Sham orbitals are often used in the chemistry community to interpret computational findings, because empirically this works ok.
But there are problems. For example, there is no guarantee that the lowest-energy Kohn-Sham solution is actually the one in which the lowest-energy orbitals are occupied (i.e. there is no reason for the Aufbau principle to hold for Kohn-Sham). And there are counterexamples [1]. Additionally for neutral and negatively-charged systems, there is no reason for the existence of HOMO-LUMO excitations and in fact already for simple cases like Helium one can prove that they don't exist [2] (in this case for LDA). This is in contrast to for example the related Hartree-Fock problem, where there always has to be a HOMO-LUMO gap [3].
With there results in mind, I would say that in general it is far-fetched to directly give KS orbitals a physical meaning. But, people have made efforts to design specific functionals or schemes, which correct on top of the orbital energies based on arguments from the derivative discontinuity. These amount to give results in agreement with ionisation potentials or electron affinites [4] and therefore could suggest that there is more to it.
So as always in physics, if you check your model applies with a higher-level theory, you might get away with using Kohn-Sham orbital energies and give them a physical interpretation, but there are definitely edge cases where this is not justified.
References
[1] Adi Makmal, Stephan Kümmel and Leeor Kronik Phys. Rev. A 83, 062512. DOI 10.1103/PhysRevA.83.062512
[2] Gero Friesecke, Benedikt Graswald arXiv:1907.00064 (pdf)
[3] Volker Bach, Elliott H. Lieb, Michael Loss and Jan Philip Solovej Phys. Rev. Lett. 72, 2981. DOI 10.1103/PhysRevLett.72.2981
[4] Andrew M. Teale, Frank De Proft, and David J. Tozer J. Chem. Phys. 129, 044110 (2008). DOI 10.1063/1.2961035.
answered May 17, 2020 at 8:13
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A few more papers to add to Michael's answer:
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JCP article titled "Increasing the applicability of density functional theory. III. Do consistent Kohn-Sham density functional methods exist?" provides Provide non-traditional view on KS eigenvalues. https://aip.scitation.org/doi/abs/10.1063/1.4755818
If one construct KS potential paying attention of xc potential that is KS eigenvalues of all occupied orbitals should be a good approximation of ionization energies one manage to construct a single correlated particle theory. As a consequence one can observe consistent behaviour in DFT results as shown in this JCP article "Increasing the applicability of density functional theory. IV. Consequences of ionization-potential improved exchange-correlation potentials" https://aip.scitation.org/doi/abs/10.1063/1.4871409
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Direct answer: it means the energy of the KS lowest-energetic orbital minimized for a specific Exchange-Correlation functional. If eventually (I don't know how to verify!) the KS lowest-energetic orbital retrieves the system orbital, it means the ground state energy of the system. To my knowledge, we have to be interested in the changes in such energy, not its value.
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1$\begingroup$ +1. "If eventually (I don't know how to verify!) the KS lowest-energetic orbital retrieves the system orbital, it means the ground state energy of the system" ... is "orbital" not a 1-electron concept? Would it really give the ground state energy of the system (i.e. the energy corresponding to the full ground-state wavefunction which is an expansion in a basis set of many orbitals)? $\endgroup$ May 16, 2020 at 21:59
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$\begingroup$ I'm having trouble interpreting this answer. Are you trying to say that the by filling the lowest energy orbitals that solve the KS equations, you get the KS ground state and thus can calculate the ground state energy? $\endgroup$– Tyberius ♦May 17, 2020 at 14:58
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$\begingroup$ @Tyberius I'm not saying that the ground state energy can be calculated after the KS ground state (or need to). What I said (or tried!) was that the DFT returns the KS orbital, not the "real" one. The KS orbital is something invented to solve the problem imposed when using the local density of charge approach for solving the multielectronic problem. It depends on the exchange-correlation functional that can, in principle, describe the system's Hamiltonian and return the desired properties, using the obtained orbitals to evaluate the expected values of the desired operator. $\endgroup$ May 17, 2020 at 15:15