基于遗传算法的施罗克二氮固定催化剂再优化

Magnus Strandgaard, Julius Seumer, Bardi Benediktsson, A. Bhowmik, T. Vegge, Jan H. Jensen
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摘要

本研究利用基于图的遗传算法(GB-GA)设计高效的固氮催化剂作为Schrock催化剂的替代品,旨在提高关键反应步骤的能量学。尽管大气中含有丰富的氮,但由于它的惰性,它在很大程度上仍然是不可接近的。Schrock催化剂,一种钼基配合物,提供了一个突破,但由于周转率低和能量瓶颈,其实际应用受到限制。本研究中的遗传算法探索了Schrock催化剂可行改性的化学空间,根据关键催化步骤的反应能和合成可达性评估每种改性催化剂的适合度。通过一系列的选择和优化过程,我们获得了20个分子在理论B3LYP水平上的完全收敛的催化循环。从这些结果中,我们确定了三个有前途的分子,每个分子在催化循环的不同方面都表现出独特的优势。这项研究为催化剂设计生成模型的潜力提供了有价值的见解。我们的研究结果可以帮助指导未来在具有挑战性的固氮过程中发现催化剂的工作。
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Genetic algorithm-based re-optimization of the Schrock catalyst for dinitrogen fixation
This study leverages a graph-based genetic algorithm (GB-GA) for the design of efficient nitrogen-fixing catalysts as alternatives to the Schrock catalyst, with the aim to improve the energetics of key reaction steps. Despite the abundance of nitrogen in the atmosphere, it remains largely inaccessible due to its inert nature. The Schrock catalyst, a molybdenum-based complex, offered a breakthrough but its practical application is limited due to low turnover numbers and energetic bottlenecks. The genetic algorithm in our study explores the chemical space for viable modifications of the Schrock catalyst, evaluating each modified catalyst’s fitness based on reaction energies of key catalytic steps and synthetic accessibility. Through a series of selection and optimization processes, we obtained fully converged catalytic cycles for 20 molecules at the B3LYP level of theory. From these results, we identified three promising molecules, each demonstrating unique advantages in different aspects of the catalytic cycle. This study offers valuable insights into the potential of generative models for catalyst design. Our results can help guide future work on catalyst discovery for the challenging nitrogen fixation process.
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