Genetic Optimization of Homogeneous Catalysts

We present the NaviCatGA package, a versatile genetic algorithm capable of optimizing molecular catalyst structures using well-suited fitness functions to achieve a set of targeted properties. The flexibility and generality of this tool are validated and demonstrated with two examples: i) Ligand optimization and exploration for Ni-catalyzed aryl-ether cleavage manipulating SMILES and using a fitness function derived from molecular volcano plots, ii) multi-objective (i. e., activity/selectivity) optimization of bipyridine N,N-dioxide Lewis basic organocatalysts for the asymmetric propargylation of benzaldehyde from 3D molecular fragments. We show that evolutionary optimization, enabled by NaviCatGA, is an efficient way of accelerating catalyst discovery through bypassing combinatorial scaling issues and incorporating compelling chemical constraints.

Genetic Optimization of Homogeneous Catalysts

Designing Heterogeneous Catalysts for Renewable Catalysis Applications Using Metal Oxide Deposition

Differences in the Concept of Fitness Between Artificial Evolution and Natural Selection

Designing Heterogeneous Catalysts for Renewable Catalysis Applications Using Metal Oxide Deposition

Differences in the Concept of Fitness Between Artificial Evolution and Natural Selection