Illuminating the Performance of Electron Withdrawing Groups in Halogen Bonding

Devore, Daniel P.; Ellington, Thomas L.; Shuford, Kevin L.

doi:10.1002/cphc.202400607

ChemPhysChem

2024

DOI: 10.1002/cphc.202400607

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Illuminating the Performance of Electron Withdrawing Groups in Halogen Bonding

Daniel P. Devore,

Thomas L. Ellington,

Kevin L. Shuford

Abstract: Throughout the halogen bonding literature, electron withdrawing groups are relied upon heavily for tuning the in‐ teraction strength between the halogen bond donor and acceptor; however, the interplay of electronic effects associated with various substituents is less of a focus. This work utilizes computational techniques to study the degree of σ‐ and π‐ electron donating/accepting character of electron withdrawing groups in a prescribed set of halo‐alkyne, halo‐benzene, and halo‐ethynyl benzene halogen bond d… Show more

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Data and Molecular Fingerprint-Driven Machine Learning Approaches to Halogen Bonding

Devore,

Shuford

2024

J. Chem. Inf. Model.

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The ability to predict the strength of halogen bonds and properties of halogen bond (XB) donors has significant utility for medicinal chemistry and materials science. XBs are typically calculated through expensive ab initio methods. Thus, the development of tools and techniques for fast, accurate, and efficient property predictions has become increasingly more important. Herein, we employ three machine learning models to classify the XB donors and complexes by their principal halogen atom as well as predict the values of the maximum point on the electrostatic potential surface (V S,max ) and interaction strength of the XB complexes through a molecular fingerprint and data-based analysis. The fingerprint analysis produces a root-mean-square error of ca. 7.5 and ca. 5.5 kcal mol −1 while predicting the V S,max for the halobenzene and haloethynylbenzene systems, respectively. However, the prediction of the binding energy between the XB donors and ammonia acceptor is shown to be within 1 kcal mol −1 of the density functional theory (DFT)-calculated energy. More accurate predictions can be made from the precalculated DFT data when compared to the fingerprint analysis.

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Data and Molecular Fingerprint-Driven Machine Learning Approaches to Halogen Bonding

Devore,

Shuford

2024

J. Chem. Inf. Model.

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Illuminating the Performance of Electron Withdrawing Groups in Halogen Bonding

Cited by 1 publication

References 74 publications

Data and Molecular Fingerprint-Driven Machine Learning Approaches to Halogen Bonding

Data and Molecular Fingerprint-Driven Machine Learning Approaches to Halogen Bonding

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