Issue 7, 2024

Tailoring phosphine ligands for improved C–H activation: insights from Δ-machine learning

Abstract

Transition metal complexes have played crucial roles in various homogeneous catalytic processes due to their exceptional versatility. This adaptability stems not only from the central metal ions but also from the vast array of choices of the ligand spheres, which form an enormously large chemical space. For example, Rh complexes, with a well-designed ligand sphere, are known to be efficient in catalyzing the C–H activation process in alkanes. To investigate the structure–property relation of the Rh complex and identify the optimal ligand that minimizes the calculated reaction energy ΔE of an alkane C–H activation, we have applied a Δ-machine learning method trained on various features to study 1743 pairs of reactants (Rh(PLP)(Cl)(CO)) and intermediates (Rh(PLP)(Cl)(CO)(H)(propyl)). Our findings demonstrate that the models exhibit robust predictive performance when trained on features derived from electron density (R2 = 0.816), and SOAPs (R2 = 0.819), a set of position-based descriptors. Leveraging the model trained on xTB-SOAPs that only depend on the xTB-equilibrium structures, we propose an efficient and accurate screening procedure to explore the extensive chemical space of bisphosphine ligands. By applying this screening procedure, we identify ten newly selected reactant–intermediate pairs with an average ΔE of 33.2 kJ mol−1, remarkably lower than the average ΔE of the original data set of 68.0 kJ mol−1. This underscores the efficacy of our screening procedure in pinpointing structures with significantly lower energy levels.

Graphical abstract: Tailoring phosphine ligands for improved C–H activation: insights from Δ-machine learning

Supplementary files

Article information

Article type
Paper
Submitted
31 Jan 2024
Accepted
27 May 2024
First published
28 May 2024
This article is Open Access
Creative Commons BY license

Digital Discovery, 2024,3, 1350-1364

Tailoring phosphine ligands for improved C–H activation: insights from Δ-machine learning

T. Huang, R. Geitner, A. Croy and S. Gräfe, Digital Discovery, 2024, 3, 1350 DOI: 10.1039/D4DD00037D

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