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Minimal-active-space multistate density functional theory for excitation energy involving local and charge transfer states

Ruoqi Zhao, Christian Hettich, Xin Chen, Jiali Gao

2021npj Computational Materials25 citationsDOIOpen Access PDF

Abstract

Multistate density functional theory (MSDFT) employing a minimum active space (MAS) is presented to determine charge transfer (CT) and local excited states of bimolecular complexes. MSDFT is a hybrid wave function theory (WFT) and density functional theory, in which dynamic correlation is first incorporated in individual determinant configurations using a Kohn-Sham exchange-correlation functional. Then, nonorthogonal configuration-state interaction is performed to treat static correlation. Because molecular orbitals are optimized separately for each determinant by including Kohn-Sham dynamic correlation, a minimal number of configurations in the active space, essential to representing low-lying excited and CT states of interest, is sufficient to yield the adiabatic states. We found that the present MAS-MSDFT method provides a good description of covalent and CT excited states in comparison with experiments and high-level computational results. Because of the simplicity and interpretive capability through diabatic configuration weights, the method may be useful in dynamic simulations of CT and nonadiabatic processes.

Topics & Concepts

DiabaticDensity functional theoryAdiabatic processExcited stateComplete active spaceExcitationTime-dependent density functional theoryOrbital-free density functional theoryWave functionHybrid functionalConfiguration spaceConfiguration interactionPhysicsAtomic physicsSpace (punctuation)Atomic orbitalCharge (physics)Quantum mechanicsMolecular physicsStatistical physicsComputer scienceOperating systemBasis setElectronPhotochemistry and Electron Transfer StudiesSpectroscopy and Quantum Chemical StudiesAdvanced Chemical Physics Studies
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