A QM-AI Approach for the Acceleration of Accurate Assessments of Halogen‑π Interactions by Training Neural Networks

A QM-AI Approach for the Acceleration of Accurate Assessments of Halogen‑π Interactions by Training Neural Networks

Noncovalent interactions, such as halogen bonds (XB), play a crucial role in molecular recognition and drug design, yet halogen···π contacts remain comparatively underexplored. Here, we report a proof-of-concept QM-AI approach that integrates high-level quantum mechanical (QM) calculations with neur...

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書誌詳細
第一著者: Marc U. Engelhardt (16642483) (author)
その他の著者: Finn Mier (21514038) (author), Markus O. Zimmermann (1284975) (author), Frank M. Boeckler (509961) (author)
出版事項: 2025
主題:
Biophysics
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
Information Systems not elsewhere classified
xb ), play
simple geometric descriptors
maintained strong performance
magnitude (∼ 10
level quantum mechanical
excellent accuracy (<
derived test sets
defined geometric constraints
better calculation efficiency
4 million mp2
2 </ sup
r </
2 orders
tzvpp single
study demonstrates
specifically designed
randomly generated
neural networks
nearly 1
molecular recognition
machine learning
integrates high
input features
herein exploit
halogen bonds
drug design
crucial role
capture σ
benchmarking study
ai approach
accurate assessments
>< sup
8 orders
16 kj
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その他の書誌記述
要約:Noncovalent interactions, such as halogen bonds (XB), play a crucial role in molecular recognition and drug design, yet halogen···π contacts remain comparatively underexplored. Here, we report a proof-of-concept QM-AI approach that integrates high-level quantum mechanical (QM) calculations with neural networks (NNs) to predict halogen···π interaction energies. Nearly 1.4 million MP2/TZVPP single-point calculations on halobenzene–benzene complexes were carried out to generate exhaustive training data, which were represented by simple geometric descriptors as input features for machine learning. The resulting neural network model is specifically designed to capture σ-hole-driven halogen···π interactions under well-defined geometric constraints. The resulting model reproduced reference interaction energies with excellent accuracy (<i>R</i><sup>2</sup> = 0.998, RMSE = 0.16 kJ/mol) and maintained strong performance on independent, randomly generated and PDB-derived test sets. Previously, we have demonstrated in a benchmarking study that “gold standard” CCSD(T) energies of this interaction can be appropriately represented by MP2/TZVPP calculations, but at a better calculation efficiency by 2 orders of magnitude (∼10<sup>2</sup>). Consequently, we herein exploit a methodological “extension” from CCSD(T) → MP2 → NNs. Our approach maintains accuracy close to CCSD(T) benchmarks while achieving a runtime acceleration of up to 8 orders of magnitude (∼10<sup>8</sup>) compared to MP2 calculations. This study demonstrates the feasibility of fast, accurate neural network models based on QM data for halogen···π interactions in a QM-AI approach.

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