Orbital energies and nuclear forces in DFT: Interpretation and validation Journal Articles

abstract

• AbstractThe bonding and antibonding character of individual molecular orbitals has been previously shown to be related to their orbital energy derivatives with respect to nuclear coordinates, known as dynamical orbital forces. Albeit usually derived from Koopmans' theorem, in this work we show a more general derivation from conceptual DFT, which justifies application in a broader context. The consistency of the approach is validated numerically for valence orbitals in Kohn–Sham DFT. Then, we illustrate its usefulness by showcasing applications in aromatic and antiaromatic systems and in excited state chemistry. Overall, dynamical orbital forces can be used to interpret the results of routine ab initio calculations, be it wavefunction or density based, in terms of forces and occupations.

authors

• Laplaza, Rubén
• Cárdenas, Carlos
• Chaquin, Patrick
• Contreras‐García, Julia
• Ayers, Paul

status

• published 

publication date

• February 15, 2021

has subject area

• 0306 Physical Chemistry (incl. Structural) (FoR)
• 0307 Theoretical and Computational Chemistry (FoR)
• 1007 Nanotechnology (FoR)
• Chemical Physics (Science Metrix)

published in

• Journal of Computational Chemistry  Journal

keywords

• conceptual density functional theory
• density functional theory
• dynamic orbital forces
• nuclear Fukui function
• nuclear forces

Digital Object Identifier (DOI)

• 10.1002/jcc.26459

PubMed ID

• 33301201

start page

• 334

end page

• 343

volume

• 42

issue

• 5