In-Depth Theoretical Investigations of Borazine's Aromaticity: Tailoring Electron Delocalization through Substituent Effects.

IF 4.2 2区化学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Molecules Pub Date : 2024-10-16 DOI:10.3390/molecules29204902

Alex-Cristian Tomut, Ionut-Tudor Moraru, Gabriela Nemes

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引用次数: 0

Abstract

The current study investigates the influence of several R substituents (e.g., Me, SiH₃, F, Cl, Br, OH, NH₂, etc.) on the aromaticity of borazine, also known as the "inorganic benzene". By performing hybrid DFT methods, blended with several computational techniques, e.g., Natural Bond Orbital (NBO), Quantum Theory of Atoms in Molecules (QTAIM), Gauge-Including Magnetically Induced Current (GIMIC), Nucleus-Independent Chemical Shift (NICS), and following a simultaneous evaluation of four different aromaticity indices (para-delocalization index (PDI), multi-centre bond order (MCBO), ring current strength (RCS), and NICS parameters), it is emphasized that the aromatic character of B-substituted (B₃R₃N₃H₃) and N-substituted (B₃H₃N₃R₃) borazine derivatives can be tailored by modulating the electronic effects of R groups. It is also highlighted that the position of R substituents on the ring structure is crucial in tuning the aromaticity. Systematic comparisons of calculated aromaticity index values (i.e., via regression analyses and correlation matrices) ensure that the reported trends in aromaticity variation are accurately described, while the influence of different R groups on electron delocalization and related aromaticity phenomena is quantitatively assessed based on NBO analyses. The most relevant interactions impacting the aromatic character of investigated systems are (i) the electron conjugations occurring between the p lone pair electrons (LP) on the F, Cl, Br, O or N atoms, of R groups, and the π*(B=N) orbitals on the borazine ring (i.e., LP(R)→π*(B=N) donations), and (ii) the steric-exchange (Pauli) interactions between the same LP and the π(B=N) bonds (i.e., LP(R)↔π(B=N) repulsions), while inductive/field effects influence the aromaticity of the investigated trisubstituted borazine systems to a much lesser extent. This work highlights that although the aromatic character of borazine can be enhanced by grafting electron-donor substituents (F, OH, NH₂, O^-, NH^-) on the N atoms, the stabilization due to aromaticity has only a moderate impact on these systems. By replacing the H substituents on the B atoms with similar R groups, the aromatic character of borazine is decreased due to strong exocyclic LP(R)→π*(B=N) donations affecting the delocalization of π-electrons on the borazine ring.

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硼嗪芳香性的深入理论研究：通过取代基效应调整电子析出。

本研究探讨了多个 R 取代基（如 Me、SiH3、F、Cl、Br、OH、NH2 等）对硼嗪（又称 "无机苯"）芳香性的影响。通过采用混合 DFT 方法，并结合多种计算技术，例如自然键轨道 (NBO)、分子中原子的量子理论 (QTAIM)、量规含磁诱导电流 (GIMIC)、核独立化学位移 (NICS)，并同时评估了四种不同的芳香指数（对位异化指数 (PDI)、多中心键阶 (MCDI)、多中心键阶 (MCF)）、多中心键序 (MCBO)、环流强度 (RCS) 和 NICS 参数），强调 B 取代 (B3R3N3H3) 和 N 取代 (B3H3N3R3) 硼嗪衍生物的芳香特性可以通过调节 R 基团的电子效应来定制。研究还强调，R 取代基在环结构上的位置对芳香度的调整至关重要。对计算出的芳香指数值进行系统比较（即通过回归分析和相关矩阵），确保准确描述所报告的芳香度变化趋势，同时根据 NBO 分析定量评估不同 R 基团对电子析出和相关芳香度现象的影响。影响所研究体系芳香特性的最相关相互作用是：(i) R 基团 F、Cl、Br、O 或 N 原子上的 p 孤对电子（LP）与硼嗪环上的 π*（B=N）轨道之间发生的电子共轭（即、LP(R)→π*(B=N)捐赠），以及 (ii) 相同 LP 与 π(B=N)键之间的立体交换（保利）相互作用（即 LP(R)↔π(B=N) 排斥），而感应/场效应对所研究的三取代硼嗪体系芳香性的影响要小得多。这项研究突出表明，虽然在 N 原子上接枝电子供体取代基（F、OH、NH2、O-、NH-）可以增强硼嗪的芳香性，但芳香性对这些体系的稳定影响不大。用类似的 R 基团取代 B 原子上的 H 取代基后，硼嗪的芳香性会因强烈的外环 LP(R)→π*(B=N)配位而降低，从而影响硼嗪环上 π 电子的脱ocal 化。

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

Molecules 化学-有机化学

CiteScore

7.40

自引率

8.70%

发文量

7524

审稿时长

1.4 months

期刊介绍： Molecules (ISSN 1420-3049, CODEN: MOLEFW) is an open access journal of synthetic organic chemistry and natural product chemistry. All articles are peer-reviewed and published continously upon acceptance. Molecules is published by MDPI, Basel, Switzerland. Our aim is to encourage chemists to publish as much as possible their experimental detail, particularly synthetic procedures and characterization information. There is no restriction on the length of the experimental section. In addition, availability of compound samples is published and considered as important information. Authors are encouraged to register or deposit their chemical samples through the non-profit international organization Molecular Diversity Preservation International (MDPI). Molecules has been launched in 1996 to preserve and exploit molecular diversity of both, chemical information and chemical substances.