Enhanced Stibine Oxide Lewis Basicity Overcomes Steric Frustration

IF 2.9 3区化学 Q2 CHEMISTRY, INORGANIC & NUCLEAR

Organometallics Pub Date : 2025-09-09 DOI:10.1021/acs.organomet.5c00212

Addis Getahun, , , John S. Wenger, , and , Timothy C. Johnstone*,

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Abstract

The characteristic electronic structure of the phosphoryl group in phosphine oxides confers great stability on the P⁺–O^– bond, in part because of back-bonding from O-based lone pairs into the P–C antibonding orbitals. The partial nature of this donation allows the O atom in the phosphoryl unit to exhibit Lewis basicity. This backbonding weakens as the atomic number of the pnictogen increases, which results in a significant enhancement in basicity for the heavier stiboryl congener. Here, we compare the ability of R₃PnO (Pn = P, As, Sb) species to bind to main-group Lewis acids. As the steric bulk of the R group increases, R₃PO and R₃AsO lose this capacity; Dipp₃PO and Dipp₃AsO (where Dipp = 2,6-diisopropylphenyl) are unable to bind even the very strong Lewis acid B(C₆F₅)₃. In contrast, the enhanced basicity of the stibine oxides allows them to overcome this steric hindrance and form adducts, even in the case of the very hindered Dipp₃SbO·B(C₆F₅)₃.

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增强氧化锑路易斯碱度克服位阻

膦氧化物中磷酰基特有的电子结构赋予了P+ - o -键极大的稳定性，部分原因是它能从基孤对回键到P - c反键轨道。这种给予的部分性质使得磷基单元中的O原子表现出路易斯碱度。这种回键随着烟原原子序数的增加而减弱，这导致较重的烟原同系物的碱度显著增强。在这里，我们比较了R3PnO （Pn = P, As, Sb）与主要基团路易斯酸结合的能力。随着R基空间体积的增大，R3PO和R3AsO失去了这种容量；Dipp3PO和Dipp3AsO（其中Dipp = 2,6-二异丙基苯基）甚至不能结合非常强的路易斯酸B(C6F5)3。相反，强碱性的锑化物氧化物使它们能够克服位阻形成加合物，即使在极受阻的Dipp3SbO·B(C6F5)3的情况下也是如此。

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

Organometallics 化学-无机化学与核化学

CiteScore

5.60

自引率

7.10%

发文量

382

审稿时长

1.7 months

期刊介绍： Organometallics is the flagship journal of organometallic chemistry and records progress in one of the most active fields of science, bridging organic and inorganic chemistry. The journal publishes Articles, Communications, Reviews, and Tutorials (instructional overviews) that depict research on the synthesis, structure, bonding, chemical reactivity, and reaction mechanisms for a variety of applications, including catalyst design and catalytic processes; main-group, transition-metal, and lanthanide and actinide metal chemistry; synthetic aspects of polymer science and materials science; and bioorganometallic chemistry.