Morgante Pierpaolo, Deluca Coty, Jones Tegla E, Aldrich Gregory J, Takenaka Norito, Peverati Roberto
Chemistry Program, Florida Institute of Technology, 150 W. University Blvd., Melbourne, FL 32901, USA.
Catalysts. 2021 Dec;11(12). doi: 10.3390/catal11121487. Epub 2021 Dec 4.
Allylation reactions of aldehydes are chemical transformations of fundamental interest, as they give direct access to chiral homoallylic alcohols. In this work, we focus on the full computational characterization of the catalytic activity of substituted biisoquinoline-N,N'-dioxides for the allylation of 2-naphthaldehyde. We characterized the structure of all transition states as well as identified the π stacking interactions that are responsible for their relative energies. Motivated by disagreement with the experimental results, we also performed an assessment of 34 different density functional methods, with the goal of assessing DFT as a general tool for understanding this chemistry. We found that the DFT results are generally consistent as long as functionals that correctly account for dispersion interactions are used. However, agreement with the experimental results is not always guaranteed. We suggest the need for a careful synergy between computations and experiments to correctly interpret the data and use them as a design tool for new and improved asymmetric catalysts.
醛的烯丙基化反应是具有根本重要性的化学转化反应,因为它们能直接得到手性高烯丙醇。在这项工作中,我们专注于对取代的双异喹啉 - N,N'-二氧化物催化2 - 萘甲醛烯丙基化反应活性的全面计算表征。我们表征了所有过渡态的结构,并确定了导致其相对能量的π堆积相互作用。由于与实验结果存在分歧,我们还对34种不同的密度泛函方法进行了评估,目的是评估密度泛函理论作为理解这种化学的通用工具。我们发现,只要使用能正确考虑色散相互作用的泛函,密度泛函理论的结果通常是一致的。然而,与实验结果的一致性并非总能得到保证。我们建议在计算和实验之间需要仔细协同,以正确解释数据并将其用作设计新型和改进型不对称催化剂的工具。