Abstract
Organoboranes are among the most versatile and widely used reagents in synthetic chemistry. A significant further expansion of their application spectrum would be achievable if boron-containing reactive intermediates capable of inserting into C-H bonds or performing nucleophilic substitution reactions were readily available. However, current progress in the field is still hampered by a lack of universal design concepts and mechanistic understanding. Herein we report that the doubly arylene-bridged diborane(6) 1H2 and its B[double bond, length as m-dash]B-bonded formal deprotonation product Li2[1] can activate the particularly inert C(sp3)-H bonds of added H3CLi and H3CCl, respectively. The first case involves the attack of [H3C]- on a Lewis-acidic boron center, whereas the second case follows a polarity-inverted pathway with nucleophilic attack of the B[double bond, length as m-dash]B double bond on H3CCl. Mechanistic details were elucidated by means of deuterium-labeled reagents, a radical clock, α,ω-dihaloalkane substrates, the experimental identification of key intermediates, and quantum-chemical calculations. It turned out that both systems, H3CLi/1H2 and H3CCl/Li2[1], ultimately funnel into the same reaction pathway, which likely proceeds past a borylene-type intermediate and requires the cooperative interaction of both boron atoms.
Highlights
The potential of boron compounds to actively promote the cleavage of element– element bonds, lay dormant until the concepts of “Boron Lewis-acid catalysis“3–6 and “Frustrated Lewis pairs”7–9 were introduced about 15 years ago
With the triad 1H2/Li[1H]/Li2[1] (Scheme 1), we recently developed a system of ditopic boranes, which is comparable to the DBA/[DBA]2À pair, because it encompasses a Lewis-acidic (1H2) together with a dianionic species ([1]2À)
C(sp3)–H activation and nucleophilic substitution reactions have been performed on the same redox-active diborane platform
Summary
Organoboranes remained limited to a passive role as reagents in organic synthesis, where boryl substituents either serve as placeholders for other functional groups (e.g., halides, hydroxy, and amino groups),1 or are involved in Pd-catalyzed C–C-coupling reactions.2 Another useful asset, the potential of boron compounds to actively promote the cleavage of element– element bonds, lay dormant until the concepts of “Boron Lewis-acid catalysis“3–6 and “Frustrated Lewis pairs”7–9 were introduced about 15 years ago.
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