Maley Steven M, Kwon Doo-Hyun, Rollins Nick, Stanley Johnathan C, Sydora Orson L, Bischof Steven M, Ess Daniel H
Department of Chemistry and Biochemistry, Brigham Young University Provo Utah 84602 USA
Research and Technology, Chevron Phillips Chemical Company LP 1862, Kingwood Drive Kingwood Texas 77339 USA
Chem Sci. 2020 Aug 21;11(35):9665-9674. doi: 10.1039/d0sc03552a.
The use of data science tools to provide the emergence of non-trivial chemical features for catalyst design is an important goal in catalysis science. Additionally, there is currently no general strategy for computational homogeneous, molecular catalyst design. Here, we report the unique combination of an experimentally verified DFT-transition-state model with a random forest machine learning model in a campaign to design new molecular Cr phosphine imine (Cr(P,N)) catalysts for selective ethylene oligomerization, specifically to increase 1-octene selectivity. This involved the calculation of 1-hexene : 1-octene transition-state selectivity for 105 (P,N) ligands and the harvesting of 14 descriptors, which were then used to build a random forest regression model. This model showed the emergence of several key design features, such as Cr-N distance, Cr-α distance, and Cr distance out of pocket, which were then used to rapidly design a new generation of Cr(P,N) catalyst ligands that are predicted to give >95% selectivity for 1-octene.
利用数据科学工具为催化剂设计提供重要的非平凡化学特征是催化科学的一个重要目标。此外,目前还没有用于计算均相分子催化剂设计的通用策略。在此,我们报告了一个经过实验验证的密度泛函理论(DFT)过渡态模型与一个随机森林机器学习模型的独特结合,旨在设计用于选择性乙烯齐聚的新型分子铬膦亚胺(Cr(P,N))催化剂,特别是提高1-辛烯的选择性。这涉及计算105种(P,N)配体的1-己烯:1-辛烯过渡态选择性,并获取14个描述符,然后用于构建随机森林回归模型。该模型显示出几个关键设计特征的出现,如Cr-N距离、Cr-α距离和口袋外的Cr距离,然后用于快速设计新一代的Cr(P,N)催化剂配体,预计其对1-辛烯的选择性大于95%。
