Computational workflow for steric assessment using the electric field-derived size

IF 2.9 Q3 CHEMISTRY, PHYSICAL
Austin Mroz, Lukas Turcani, Kim Jelfs
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Abstract

Abstract Molecular structure plays an important role in the selectivity and performance of catalysts. Understanding the impact of structural differences on catalyst performance via quantitative structure-selectivity relationships is key to developing high-performing catalytic systems. There are several methods that have been introduced to quantify steric contributions, including Tolman cone angles, Charton parameters, and A-values. While these have shown promise in predicting selectivity, they access similar, general steric contributions and are largely empirically derived. Alternatively, Sterimol parameters offer a specific multi-directional measure of steric bulk in the form of three vectors in units of distance. Recently, these parameters revealed strong correlations between structure and selectivity in asymmetric catalysis. Yet, despite their demonstrated performance, Sterimol parameters are commonly derived using van der Waals radii, which approximate molecular size using hard-spheres. This method may not accurately describe highly polarized systems. Recently, a new chemical system size metric based on the electric-field of a molecule was developed, which accesses the occupied space of a molecule. Here, we demonstrate that the electric field-derived Sterimol parameters reveal similar structure-selectivity relationships in asymmetric catalysis as conventional Sterimol parameters. Specifically, we present a computational workflow for calculating Sterimol parameters based on the size of a molecule’s electric field, and validate our method using several asymmetric catalysis reactions.
使用电场导出尺寸进行立体评估的计算工作流程
摘要分子结构对催化剂的选择性和性能起着重要作用。通过定量结构-选择性关系了解结构差异对催化剂性能的影响是开发高性能催化体系的关键。已经引入了几种方法来量化空间贡献,包括托尔曼锥角、查顿参数和a值。虽然这些在预测选择性方面显示出了希望,但它们获得了类似的,一般的空间贡献,并且主要是经验推导出来的。另外,Sterimol参数以距离单位的三个矢量的形式提供了特定的多向立体体积测量。近年来,这些参数揭示了不对称催化的结构与选择性之间的密切关系。然而,尽管Sterimol的性能已经得到了证明,但它们的参数通常是用范德华半径推导出来的,而范德华半径是用硬球近似分子大小的。这种方法可能不能准确地描述高度极化的系统。近年来,人们提出了一种基于分子电场的化学体系尺寸度量方法,该方法可以获得分子的占据空间。在这里,我们证明了电场衍生的Sterimol参数在不对称催化中表现出与传统Sterimol参数相似的结构-选择性关系。具体来说,我们提出了一个基于分子电场大小计算Sterimol参数的计算流程,并通过几个不对称催化反应验证了我们的方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.70
自引率
11.50%
发文量
46
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