In Silico Chemical Experiments in the Age of AI: From Quantum Chemistry to Machine Learning and Back

Aldossary, Abdulrahman; Campos‐Gonzalez‐Angulo, Jorge Arturo; Pablo‐García, Sergio; Leong, Shi Xuan; Rajaonson, Ella Miray; Thiede, Luca; Tom, Gary; Wang, Andrew; Avagliano, Davide; Aspuru‐Guzik, Alán

doi:10.1002/adma.202402369

Advanced Materials

2024

DOI: 10.1002/adma.202402369

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In Silico Chemical Experiments in the Age of AI: From Quantum Chemistry to Machine Learning and Back

Abdulrahman Aldossary,

Jorge Arturo Campos‐Gonzalez‐Angulo,

Sergio Pablo‐García

et al.

Abstract: Computational chemistry is an indispensable tool for understanding molecules and predicting chemical properties. However, traditional computational methods face significant challenges due to the difficulty of solving the Schrödinger equations and the increasing computational cost with the size of the molecular system. In response, there has been a surge of interest in leveraging artificial intelligence (AI) and machine learning (ML) techniques to in silico experiments. Integrating AI and ML into computational … Show more

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Cited by 8 publications

References 451 publications

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Computational Modeling of Reticular Materials: The Past, the Present, and the Future

Temmerman,

Goeminne,

Rawat

et al. 2024

Advanced Materials

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Reticular materials rely on a unique building concept where inorganic and organic building units are stitched together giving access to an almost limitless number of structured ordered porous materials. Given the versatility of chemical elements, underlying nets, and topologies, reticular materials provide a unique platform to design materials for timely technological applications. Reticular materials have now found their way in important societal applications, like carbon capture to address climate change, water harvesting to extract atmospheric moisture in arid environments, and clean energy applications. Combining predictions from computational materials chemistry with advanced experimental characterization and synthesis procedures unlocks a design strategy to synthesize new materials with the desired properties and functions. Within this review, the current status of modeling reticular materials is addressed and supplemented with topical examples highlighting the necessity of advanced molecular modeling to design materials for technological applications. This review is structured as a templated molecular modeling study starting from the molecular structure of a realistic material towards the prediction of properties and functions of the materials. At the end, the authors provide their perspective on the past, present of future in modeling reticular materials and formulate open challenges to inspire future model and method developments.

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Computational Modeling of Reticular Materials: The Past, the Present, and the Future

Temmerman,

Goeminne,

Rawat

et al. 2024

Advanced Materials

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Can Deep Learning Search for Exceptional Chiroptical Properties? The Halogenated [6]Helicene Case

Uceda,

Gijón,

Míguez‐Lago

et al. 2024

Angewandte Chemie

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The relationship between chemical structure and chiroptical properties is not always clearly understood. Nowadays, efforts to develop new systems with enhanced optical properties follow the trial‐error method. A large number of data would allow us to obtain more robust conclusions and guide research toward molecules with practical applications. In this sense, in this work we predict the chiroptical properties of millions of halogenated [6]helicenes in terms of the rotatory strength (R). We have used DFT calculations to randomly create derivatives including from 1 to 16 halogen atoms, that were then used as a data set to train different deep neural network models. These models allow us to i) predict the Rmax for any halogenated [6]helicene with a very low computational cost, and ii) to understand the physical reasons that favour some substitutions over others. Finally, we synthesized derivatives with higher predicted Rmax obtaining excellent correlation among the values obtained experimentally and the predicted ones.

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Can Deep Learning Search for Exceptional Chiroptical Properties? The Halogenated [6]Helicene Case

Uceda,

Gijón,

Míguez‐Lago

et al. 2024

Angew Chem Int Ed

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In Silico Chemical Experiments in the Age of AI: From Quantum Chemistry to Machine Learning and Back

Cited by 8 publications

References 451 publications

Computational Modeling of Reticular Materials: The Past, the Present, and the Future

Computational Modeling of Reticular Materials: The Past, the Present, and the Future

Can Deep Learning Search for Exceptional Chiroptical Properties? The Halogenated [6]Helicene Case

Can Deep Learning Search for Exceptional Chiroptical Properties? The Halogenated [6]Helicene Case

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