%AMao, Yuezhi%AMao, Yuezhi [Department of Chemistry, Stanford University, Stanford, California 94305, USA]%AMontoya-Castillo, Andrés%AMontoya-Castillo, Andrés [Department of Chemistry, Stanford University, Stanford, California 94305, USA]%AMarkland, Thomas%AMarkland, Thomas [Department of Chemistry, Stanford University, Stanford, California 94305, USA]%BJournal Name: The Journal of Chemical Physics; Journal Volume: 153; Journal Issue: 24; Related Information: CHORUS Timestamp: 2023-06-26 15:34:44 %D2020%IAmerican Institute of Physics %JJournal Name: The Journal of Chemical Physics; Journal Volume: 153; Journal Issue: 24; Related Information: CHORUS Timestamp: 2023-06-26 15:34:44 %K %MOSTI ID: 10207220 %PMedium: X %TExcited state diabatization on the cheap using DFT: Photoinduced electron and hole transfer %X

Excited state electron and hole transfer underpin fundamental steps in processes such as exciton dissociation at photovoltaic heterojunctions, photoinduced charge transfer at electrodes, and electron transfer in photosynthetic reaction centers. Diabatic states corresponding to charge or excitation localized species, such as locally excited and charge transfer states, provide a physically intuitive framework to simulate and understand these processes. However, obtaining accurate diabatic states and their couplings from adiabatic electronic states generally leads to inaccurate results when combined with low-tier electronic structure methods, such as time-dependent density functional theory, and exorbitant computational cost when combined with high-level wavefunction-based methods. Here, we introduce a density functional theory (DFT)-based diabatization scheme that directly constructs the diabatic states using absolutely localized molecular orbitals (ALMOs), which we denote as Δ-ALMO(MSDFT2). We demonstrate that our method, which combines ALMO calculations with the ΔSCF technique to construct electronically excited diabatic states and obtains their couplings with charge-transfer states using our MSDFT2 scheme, gives accurate results for excited state electron and hole transfer in both charged and uncharged systems that underlie DNA repair, charge separation in donor–acceptor dyads, chromophore-to-solvent electron transfer, and singlet fission. This framework for the accurate and efficient construction of excited state diabats and evaluation of their couplings directly from DFT thus offers a route to simulate and elucidate photoinduced electron and hole transfer in large disordered systems, such as those encountered in the condensed phase.

%0Journal Article