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Auteurs principaux: Lyu, Dongyu, Holzenkamp, Matthias, Vinod, Vivin, Holtkamp, Yannick Marcel, Maity, Sayan, Salazar, Carlos R., Kleinekathöfer, Ulrich, Zaspel, Peter
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2410.20551
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author Lyu, Dongyu
Holzenkamp, Matthias
Vinod, Vivin
Holtkamp, Yannick Marcel
Maity, Sayan
Salazar, Carlos R.
Kleinekathöfer, Ulrich
Zaspel, Peter
author_facet Lyu, Dongyu
Holzenkamp, Matthias
Vinod, Vivin
Holtkamp, Yannick Marcel
Maity, Sayan
Salazar, Carlos R.
Kleinekathöfer, Ulrich
Zaspel, Peter
contents Natural light-harvesting antenna complexes efficiently capture solar energy using chlorophyll, i.e., magnesium porphyrin pigments, embedded in a protein matrix. Inspired by this natural configuration, artificial clay-porphyrin antenna structures have been experimentally synthesized and have demonstrated remarkable excitation energy transfer properties. The study presents the computational design and simulation of a synthetic light-harvesting system that emulates natural mechanisms by arranging cationic free-base porphyrin molecules on an anionic clay surface. We investigated the transfer of excitation energy among the porphyrin dyes using a multiscale quantum mechanics/molecular mechanics (QM/MM) approach based on the semi-empirical density functional-based tight-binding (DFTB) theory for the ground state dynamics. To improve the accuracy of our results, we incorporated an innovative multifidelity machine learning (MFML) approach, which allows the prediction of excitation energies at the numerically demanding time-dependent density functional theory level with the Def2-SVP basis set. This approach was applied to an extensive dataset of 640K geometries for the 90-atom porphyrin structures, facilitating a thorough analysis of the excitation energy diffusion among the porphyrin molecules adsorbed to the clay surface. The insights gained from this study, inspired by natural light-harvesting complexes, demonstrate the potential of porphyrin-clay systems as effective energy transfer systems.
format Preprint
id arxiv_https___arxiv_org_abs_2410_20551
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Excitation Energy Transfer between Porphyrin Dyes on a Clay Surface: A study employing Multifidelity Machine Learning
Lyu, Dongyu
Holzenkamp, Matthias
Vinod, Vivin
Holtkamp, Yannick Marcel
Maity, Sayan
Salazar, Carlos R.
Kleinekathöfer, Ulrich
Zaspel, Peter
Chemical Physics
Natural light-harvesting antenna complexes efficiently capture solar energy using chlorophyll, i.e., magnesium porphyrin pigments, embedded in a protein matrix. Inspired by this natural configuration, artificial clay-porphyrin antenna structures have been experimentally synthesized and have demonstrated remarkable excitation energy transfer properties. The study presents the computational design and simulation of a synthetic light-harvesting system that emulates natural mechanisms by arranging cationic free-base porphyrin molecules on an anionic clay surface. We investigated the transfer of excitation energy among the porphyrin dyes using a multiscale quantum mechanics/molecular mechanics (QM/MM) approach based on the semi-empirical density functional-based tight-binding (DFTB) theory for the ground state dynamics. To improve the accuracy of our results, we incorporated an innovative multifidelity machine learning (MFML) approach, which allows the prediction of excitation energies at the numerically demanding time-dependent density functional theory level with the Def2-SVP basis set. This approach was applied to an extensive dataset of 640K geometries for the 90-atom porphyrin structures, facilitating a thorough analysis of the excitation energy diffusion among the porphyrin molecules adsorbed to the clay surface. The insights gained from this study, inspired by natural light-harvesting complexes, demonstrate the potential of porphyrin-clay systems as effective energy transfer systems.
title Excitation Energy Transfer between Porphyrin Dyes on a Clay Surface: A study employing Multifidelity Machine Learning
topic Chemical Physics
url https://arxiv.org/abs/2410.20551