Author: ["Holger Braunschweig","Qing Ye","Alfredo Vargas","Rian D. Dewhurst","Krzysztof Radacki","Alexander Damme"]
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Abstract
Only a handful of elements are able to be controllably homocatenated (that is, to be formed into one- or two-dimensional chains or rings of the element), because most have weak element–element bonds. Boron forms strong B–B bonds, but its favourable cluster formation makes homocatenation very difficult. Recently, the coupling of borylene (:BR) ligands on a metal was predicted computationally. We have brought this prediction to fruition experimentally, and extended it by adding two further borylene units, stepwise forming a B4 chain bound to a metal under mild conditions. This complex is a useful model for understanding the metal–boron interactions required to promote transition of the boron atoms from borylene ligands to oligoborane networks bound side-on. The concept shows great promise for the controlled construction of one-dimensional boron chains. Mild, controllable homocatenation of many elements is a considerable challenge, usually due to their low homonuclear σ-bond enthalpy. This is particularly difficult for boron, despite its high homonuclear σ -bond enthalpy. The controllable metal-templated catenation of four boron atoms is now demonstrated — a step towards oligomers of monovalent boron and polyboranes. Cite this article
Braunschweig, H., Ye, Q., Vargas, A. et al. Controlled homocatenation of boron on a transition metal. Nature Chem 4, 563–567 (2012). https://doi.org/10.1038/nchem.1379 