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CS 和 CS 桥联十硼烷类似物的化学:规则配位与簇扩展。

Chemistry of CS and CS Bridged Decaborane Analogues: Regular Coordination Versus Cluster Expansion.

机构信息

Department of Chemistry, Indian Institute of Technology Madras, Chennai 600036, India.

Univ Rennes, CNRS, Institut des Sciences Chimiques de Rennes, UMR 6226, F-35000 Rennes, France.

出版信息

Molecules. 2023 Jan 19;28(3):998. doi: 10.3390/molecules28030998.

DOI:10.3390/molecules28030998
PMID:36770666
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9919328/
Abstract

In an effort to synthesize metallaheteroborane clusters of higher nuclearity, the reactivity of metallaheteroboranes, -[(CpM)BSH(CS)] (Cp = CMe) (: M = Co; : M = Rh) with various metal carbonyls have been investigated. Photolysis of - and - with group 6 metal carbonyls, M'(CO).THF (M' = Mo or W) were performed that led to the formation of a series of adducts [(CpM)BSH(CS){M'(CO)}] (: M = Co, M' = Mo; : M = Co, M' = W; : M = Rh, M' = Mo; : M = Rh, M' = W) instead of cluster expansion reactions. In these adducts, the S atom of C=S group of di(thioboralane)thione {BCS} moiety is coordinated to M'(CO) (M = Mo or W) in -fashion. On the other hand, thermolysis of - with Ru(CO) yielded one fused metallaheteroborane cluster [{Ru(CO)}S{Ru(CO)}{Ru(CO)}CoBSH(CHS){Ru(CO)}S], . This 20-vertex-fused cluster is composed of two tetrahedral {RuS} and {RuB}, a flat butterfly {RuS} and one octadecahedron {CoRuBS} core with one missing vertex, coordinated to {RuSCHS} through two boron and one ruthenium atom. On the other hand, the room temperature reaction of - with Co(CO) produced one 19-vertex fused metallaheteroborane cluster [(CpRh)BHS{Co(CO)}{Co(CO)}(-CO)S{Co(CO)}], . Cluster contains one -decaborane {RhBS}, one butterfly {CoS} and one bicapped square pyramidal {CoS} unit that exhibits an intercluster fusion with two sulfur atoms in common. Clusters - have been characterized by multinuclear NMR and IR spectroscopy, mass spectrometry and structurally determined by XRD analyses. Furthermore, the DFT calculations have been carried out to gain insight into electronic, structural and bonding patterns of the synthesized clusters.

摘要

为了合成更高核的金属杂硼烷簇,我们研究了金属杂硼烷 -[(CpM)BSH(CS)](Cp=CMe:M=Co;:M=Rh)与各种金属羰基化合物的反应性。用第六族金属羰基化合物 M'(CO).THF(M'=Mo 或 W)对 -和 -进行光解,导致形成一系列加合物 [(CpM)BSH(CS){M'(CO)}](:M=Co,M'=Mo;:M=Co,M'=W;:M=Rh,M'=Mo;:M=Rh,M'=W),而不是簇扩展反应。在这些加合物中,二(硫代硼烷)硫酮 {BCS} 部分的 C=S 基团的 S 原子以 - fashion 与 M'(CO)(M=Mo 或 W)配位。另一方面,-与 Ru(CO)的热解反应得到一个融合的金属杂硼烷簇 [{Ru(CO)}S{Ru(CO)}{Ru(CO)}CoBSH(CHS){Ru(CO)}S],。这个 20 个顶点融合的簇由两个四面体 {RuS} 和 {RuB}、一个扁平的蝴蝶 {RuS} 和一个十八面体 {CoRuBS} 核组成,其中一个缺失顶点,通过两个硼原子和一个钌原子与 {RuSCHS} 配位。另一方面,-与 Co(CO)在室温下反应生成一个 19 个顶点融合的金属杂硼烷簇 [(CpRh)BHS{Co(CO)}{Co(CO)}(-CO)S{Co(CO)}],。簇包含一个 -decaborane {RhBS}、一个蝴蝶 {CoS} 和一个双帽四方锥 {CoS} 单元,该单元通过两个共用的硫原子表现出分子间融合。通过多核 NMR 和 IR 光谱、质谱和 XRD 分析对簇进行了表征。此外,还进行了 DFT 计算,以深入了解合成簇的电子、结构和键合模式。

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