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Main Authors: Vishal Kumar Jaiswal, Mario Taddei, Daniel R. Nascimento, Marco Garavelli, Irene Conti, Artur Nenov
Format: Artículo Open Access
Published: Wiley 2024
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Online Access:https://onlinelibrary.wiley.com/doi/10.1111/php.13922
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author Vishal Kumar Jaiswal
Mario Taddei
Daniel R. Nascimento
Marco Garavelli
Irene Conti
Artur Nenov
author_facet Vishal Kumar Jaiswal
Mario Taddei
Daniel R. Nascimento
Marco Garavelli
Irene Conti
Artur Nenov
Vishal Kumar Jaiswal
Mario Taddei
Daniel R. Nascimento
Marco Garavelli
Irene Conti
Artur Nenov
collection Wiley Open Access
contents Reconciling TD‐DFT and CASPT2 electronic structure methods for describing the photophysics of DNA Vishal Kumar Jaiswal Mario Taddei Daniel R. Nascimento Marco Garavelli Irene Conti Artur Nenov Photochemistry and Photobiology AbstractTime‐dependent density functional theory (TD‐DFT) and multiconfigurational second‐order perturbation theory (CASPT2) are two of the most widely used methods to investigate photoinduced dynamics in DNA‐based systems. These methods sometimes give diverse dynamics in physiological environments usually modeled by quantum mechanics/molecular mechanics (QM/MM) protocol. In this work, we demonstrate for the uridine test case that the underlying topology of the potential energy surfaces of electronic states involved in photoinduced relaxation is similar in both electronic structure methods. This is verified by analyzing surface‐hopping dynamics performed at the QM/MM level on aqueous solvated uridine at TD‐DFT and CASPT2 levels. By constraining the dynamics to remain on state we observe similar fluctuations in energy and relaxation lifetimes in surface‐hopping dynamics in both TD‐DFT and experimentally validated CASPT2 methods. This finding calls for a systematic comparison of the ES potential energy surfaces of DNA and RNA nucleosides at the single‐ and multi‐reference levels of theory. The anomalous long excited state lifetime at the TD‐DFT level is explained by trapping due to the tendency of TD‐DFT in QM/MM schemes with electrostatic embedding to underestimate the energy of the state leading to a wrong energetic order. A study of the FC energetics suggests that improving the description of the surrounding environment through polarizable embedding or by the expansion of QM layer with hydrogen‐bonded waters helps restore the correct state order at TD‐DFT level. Thus by combining TDDFT with an accurate modeling of the environment, TD‐DFT is positioned as the standout protocol to model photoinduced dynamics in DNA‐based aggregates and multimers. 10.1111/php.13922 http://onlinelibrary.wiley.com/termsAndConditions#vor
doi_str_mv 10.1111/php.13922
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institution Wiley Open Access
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publisher Wiley
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spellingShingle Reconciling TD‐DFT and CASPT2 electronic structure methods for describing the photophysics of DNA
Vishal Kumar Jaiswal
Mario Taddei
Daniel R. Nascimento
Marco Garavelli
Irene Conti
Artur Nenov
Photochemistry and Photobiology
Reconciling TD‐DFT and CASPT2 electronic structure methods for describing the photophysics of DNA Vishal Kumar Jaiswal Mario Taddei Daniel R. Nascimento Marco Garavelli Irene Conti Artur Nenov Photochemistry and Photobiology AbstractTime‐dependent density functional theory (TD‐DFT) and multiconfigurational second‐order perturbation theory (CASPT2) are two of the most widely used methods to investigate photoinduced dynamics in DNA‐based systems. These methods sometimes give diverse dynamics in physiological environments usually modeled by quantum mechanics/molecular mechanics (QM/MM) protocol. In this work, we demonstrate for the uridine test case that the underlying topology of the potential energy surfaces of electronic states involved in photoinduced relaxation is similar in both electronic structure methods. This is verified by analyzing surface‐hopping dynamics performed at the QM/MM level on aqueous solvated uridine at TD‐DFT and CASPT2 levels. By constraining the dynamics to remain on state we observe similar fluctuations in energy and relaxation lifetimes in surface‐hopping dynamics in both TD‐DFT and experimentally validated CASPT2 methods. This finding calls for a systematic comparison of the ES potential energy surfaces of DNA and RNA nucleosides at the single‐ and multi‐reference levels of theory. The anomalous long excited state lifetime at the TD‐DFT level is explained by trapping due to the tendency of TD‐DFT in QM/MM schemes with electrostatic embedding to underestimate the energy of the state leading to a wrong energetic order. A study of the FC energetics suggests that improving the description of the surrounding environment through polarizable embedding or by the expansion of QM layer with hydrogen‐bonded waters helps restore the correct state order at TD‐DFT level. Thus by combining TDDFT with an accurate modeling of the environment, TD‐DFT is positioned as the standout protocol to model photoinduced dynamics in DNA‐based aggregates and multimers. 10.1111/php.13922 http://onlinelibrary.wiley.com/termsAndConditions#vor
title Reconciling TD‐DFT and CASPT2 electronic structure methods for describing the photophysics of DNA
topic Photochemistry and Photobiology
url https://onlinelibrary.wiley.com/doi/10.1111/php.13922