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Combinatorial Chemistry. O. P. O. C. H. 3. polarity. backbone. selectivity. TOF. ligating group. size. residue. TON. flexibility. A. C. B. Backbone Diversity Analysis in Catalyst Design. Ana Maldonado, Gadi Rothenberg
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Combinatorial Chemistry O P O C H 3 polarity backbone selectivity TOF ligating group size residue TON flexibility A C B Backbone Diversity Analysis in Catalyst Design • Ana Maldonado, Gadi Rothenberg • Van ‘t Hoff Institute for Molecular Sciences, University of Amsterdam, The Netherlands. • maldonad@science.uva.nl A world of possibilities In homogeneous catalysis, the combination of laboratory automation and advanced modelling algorithms puts us on the brink of in silico catalyst design. To realise this goal, we must assemble and screen virtual libraries of ligand-metal complexes (Figure 1). Catalyst selection is the major problem. Generating millions of structures via computer is easy, but how should we choose the candidates for synthesis and testing? Scheme 1. Nickel Catalysed Hydrocyanation of butadiene in the Nylon process. The backbone dataset is described using three main attributes: size, flexibility, and polarity, extracted from a list of 168 computed descriptors. PCA score plots (Figure 3) as well as descriptor maps (Figure 4) were built for the backbone dataset. Diversity analysis was done by computing the average distance of each catalyst to all other catalysts in Figure 4. Figure 1. Left: catalyst decomposition framework in building blocks. Right: a catalyst space generated by thousands of combinations. Backbone Diversity holds the key The ligand backbone often dictates the ligand size and flexibility, which are related to the reaction pocket environment and the catalytic performance. Choosing the right backbone is a crucial step in ligand design. By analysing the backbone diversity in the descriptor space (space B, Figure 2) we can generate a diverse spread of ligand-metal complexes over a given catalyst space A. Figure 3. PCA score plot of the backbone dataset. Zero centred graph is shown in blue. Green circles shows clusters and red circles outliers. Figure 2. Space A (the catalyst space), is a grid containing the metal-ligand complexes. Space B (the descriptor space) contains the values of the catalyst descriptors, and space C contains the figures of merit. Figure 3. Backbone 3D descriptor space The combination of the original 42 backbones with 10 ligating groups and 20 residues, represents a catalyst space of 1.1×109 possible combinations. Sampling even 1% of this is practically impossible. Our selected subset of 24 representative backbones correspond to 10.000 bidentate catalysts, which represents a reasonable 3.79% of the 2.6×105 total combinations. What’s next? This database serves as a basis for further QSAR and in silico catalyst design for the Ni-catalyzed hydrocyanation of butadiene. Application to hydrocyanation catalysis We examined a group of 42 backbones of a set of biphosphite and biphosphine ligand-nickel complexes used for catalysing the hydrocyanation of butadiene to adiponitrile (Scheme 1). Each catalyst was divided into two L ligating groups, a backbone B, and the residue groups R (Figure 1). This division gives a standard framework for backbone comparison. References. 1. Understanding ligand diversity. J. A. Westerhuis, J. A. Hageman, H. -W. Frühauf and G. Rothenberg, Chim. Oggi - Chemistry Today, 25, 28-32 (2007). 2. Molecular Similarity and Diversity: Concepts and Applications. A. G. Maldonado, M. Petitjean, J.-P. Doucet and B.T. Fan., Molecular Diversity, 10, 39-79 (2006).