Główne pojęcia
This research demonstrates a novel approach to catalyst discovery by combining Hammett σ constants with machine learning, specifically for the Suzuki-Miyaura cross-coupling reaction, leading to the identification of promising, cost-effective catalyst candidates.
Streszczenie
Bibliographic Information:
Rakotonirina, V.D., Bragato, M., Heinen, S., & von Lilienfeld, O.A. (2024). Combining Hammett σ constants for ∆-machine learning and catalyst discovery. [Journal Name Not Provided].
Research Objective:
This study investigates the effectiveness of combining Hammett σ constants with machine learning (∆-ML) to predict relative substrate binding energies in homogeneous organometallic catalysis, specifically for the Suzuki-Miyaura (SM) cross-coupling reaction. The goal is to develop a computationally efficient method for catalyst discovery and ligand tuning.
Methodology:
The researchers employed a combination rule-enhanced Hammett-inspired product model (cHIP) to partition the contributions of metals and ligands in organometallic catalysts. They utilized two datasets: DB1, containing relative binding energies for the oxidative addition step in the SM reaction, and DB2, containing relative binding free energies for all three intermediate steps. The cHIP model was used as a baseline for ∆-ML with Kernel Ridge Regression (KRR) to improve prediction accuracy.
Key Findings:
- The cHIP model, incorporating an additive combination rule for ligand effects, demonstrated promising predictive power for relative binding energies, comparable to density functional approximations.
- Combining cHIP with ∆-ML significantly improved prediction accuracy, reaching chemical accuracy (∼1 kcal/mol) with approximately 20,000 training instances.
- Applying cHIP to a smaller dataset (DB2) enabled the prediction of relative binding free energy changes for 720 new catalysts (DB3).
- This combinatorial approach identified 145 promising catalyst candidates, including several cost-effective Ni-based catalysts, such as Aphos-Ni-P(t-Bu)3.
Main Conclusions:
The study highlights the efficacy of combining Hammett σ constants with machine learning for catalyst discovery. The proposed cHIP model, particularly when used as a baseline for ∆-ML, offers a computationally efficient and accurate method for predicting relative binding energies and identifying promising catalyst candidates.
Significance:
This research contributes to the field of computational catalysis by providing a novel approach for catalyst design and optimization. The ability to predict catalyst performance based on readily available parameters like Hammett σ constants has the potential to accelerate the discovery of new and improved catalysts for various chemical reactions.
Limitations and Future Research:
Further research is needed to investigate the effect of steric hindrance and specific ligand environments on the accuracy of the cHIP model. Additionally, extending this approach to other catalytic reactions and complexes with more than two ligands would broaden its applicability.
Statystyki
The cHIP model achieved a mean absolute error (MAE) of ~3.4 kcal/mol for DB1.
The naive HIP model, using global σs, had an MAE of ~2.5 kcal/mol.
∆-ML with cHIP as a baseline reached chemical accuracy (MAE ~1 kcal/mol) with ~20k training instances.
cHIP predicted ligand effects for 120 new ligand combinations from 16 single ligand effects.
145 new catalyst candidates displayed oxidative addition relative binding free energies ranging from -34.0 to 17.0 kcal/mol, an optimal range identified in previous research.
Aphos-Ni-P(t-Bu)3, the most cost-effective catalyst identified, represents about 67% of the cost of the least expensive catalyst in DB2.
Cytaty
"This method facilitates computational ligand tuning through binding energy predictions and their implementation into volcano plots."
"Despite the advances, these models often require extensive computations for each catalyst, highlighting the need for a combinatorial strategy that can efficiently explore the catalyst space by integrating the contributions of various building blocks, such as ligands and metals, to optimize performance."
"This combinatorial approach revealed several Ni-based catalysts approaching the top of the volcano after ligand tuning, despite the initially strong-binding nature of Ni."