We introduce a multicentered valence electron effective potential (MC-VEEP) description of functional groups which succeeds even in the context of excited electronic states. The MC-VEEP is formulated within the ansatz which is familiar for effective core potentials in quantum chemistry, and so can be easily incorporated in any quantum chemical calculation. By demanding that both occupied and virtual orbitals are described correctly on the MC-VEEP, we are able to ensure correct behavior even when the MC-VEEP borders an electronically excited region. However, the present formulation does require that the electrons represented by the MC-VEEP are primarily spectators and not directly participating in the electronic excitation. We point out the importance of separating the electrostatic and exchange-repulsion components of the MC-VEEP in order that interactions between the effective potential and other nuclei can be modeled correctly. We present a MC-VEEP for methyl radical with one active electron which is tested in several conjugated molecules. We discuss the use of the MC-VEEP as a solution to the “link atom” problem in hybrid quantum mechanical/molecular mechanical methods. We also discuss the limitations and further development of this approach.

Topics
Quantum chemistry, Excitation energies, Effective core potentials, Ab initio multiple spawning, Potential energy surfaces, Quantum mechanical/molecular mechanical calculations, Electrostatics, Intermolecular forces, Electronic excitation, Operator theory
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