Cleavage of Si–H, B–H, and C–H Bonds by Metal–Ligand Cooperation

Higashi, Takuya; Kusumoto, Shuhei; Nozaki, Kyoko

doi:10.1021/acs.chemrev.9b00262

Cited by 102 publications

(68 citation statements)

References 80 publications

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“…One way to activate B−H bonds by transition metal complexes is the oxidative addition, that is the homolytic cleavage of a B−H bond on the central metal to generate a B anion and an H anion. Alternatively, metal–ligand cooperative heterolytic cleavage has been attracting emerging attention in the last decade [7–9] . Figure 1 summarizes the representative reports for B−H bond cleavage by metal–ligand cooperation: a) ruthenium thiolate by Ohki, Tatsumi, and Oestreich, [10] b) N,O‐chelated phosphoramidate by Schafer, Love, and Weller, [11] c) palladium carbene by Iluc, [12] and d) cyclopentadienone ruthenium dimer by Casey and Clark [13] .…”

Section: Figurementioning

confidence: 99%

“…Figure 1 summarizes the representative reports for B−H bond cleavage by metal–ligand cooperation: a) ruthenium thiolate by Ohki, Tatsumi, and Oestreich, [10] b) N,O‐chelated phosphoramidate by Schafer, Love, and Weller, [11] c) palladium carbene by Iluc, [12] and d) cyclopentadienone ruthenium dimer by Casey and Clark [13] . In all of these precedents, each B−H bond is cleaved into an H anion on the metal and a B cation on the electronegative atom of the ligand, which is inheriting the polarization in the parent B−H bonds [9] . To the best of our knowledge, there is no report for the cleavage of a B−H bond with a metal‐ligand bifunctional complex to give a B anion on the metal and an H cation on the ligand [14]…”

Section: Figurementioning

confidence: 99%

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Umpolung of B−H Bonds by Metal–Ligand Cooperation with Cyclopentadienone Iridium Complexes

2020

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In contrast to conventional metal–ligand cooperative cleavage of a B−H bond, which provides a B cation on the ligand and an H anion on the metal, we report herein the umpolung of B−H bonds by novel cyclopentadienone iridium complexes. The B−H bonds of 4,4,5,5‐tetramethyl‐1,3,2‐dioxaborolane (HBpin) and 1,8‐naphthalenediaminatoborane (HBdan) were cleaved to give a B anion on the metal and an H cation on the phenolic oxygen atom of the ligand. Mechanistic investigation by DFT calculations revealed that the alkoxycarbonyl‐substituted cyclopentadienone ligand facilitated deprotonation from Ir−H after oxidative addition of the B−H bond to give the umpolung product. The generated boryliridium complex was found to undergo borylation of an allyl halide in the presence of base, thus showing the nucleophilic nature of the boron atom.

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Section: Figurementioning

confidence: 99%

Section: Figurementioning

confidence: 99%

Umpolung of B−H Bonds by Metal–Ligand Cooperation with Cyclopentadienone Iridium Complexes

2020

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“…A key feature is the cooperative H 2 ‐formation from the ligand‐based H δ + and the Ru‐H δ – in a cis ‐arrangement. Besides, MLC has found broad application in the activation of Si–H, B–H, and C–H bonds and their catalytic transformations . Most often, the ligand acts as a nucleophile and the metal as an electrophile.…”

Section: Introduction and Scopementioning

confidence: 99%

Element‐Ligand Cooperativity with p‐Block Elements

et al. 2020

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Metal‐ligand cooperativity (MLC) had a tremendous impact on d‐block metal‐mediated bond activation and homogeneous catalysis. Is this concept translatable to the elements of the p‐block? Are there analogies already at hand? In this review, we describe contributions in which a p‐block element (group 13–15) and its ligand (surrounding molecular framework) operate synergistically in a substrate activation or a catalytic cycle. This activity is termed element‐ligand cooperativity (ELC), in correspondence to MLC. After the concepts of p‐block low‐valent states and frustrated Lewis pairs mimicking the ambiphilic reactivity of transition metals, the spatial proximity of nucleophilic and electrophilic reaction sites and a small HOMO‐LUMO gap in a p‐block ELC complex might offer yet another approach. Selected examples shall illustrate common reactivities of ELC, disclose conceptual analogies with d‐block MLC, and outline shortcomings in this field.

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“…[13] In all of these precedents, each B À H bond is cleaved into an H anion on the metal and a B cation on the electronegative atom of the ligand, which is inheriting the polarization in the parent BÀH bonds. [9] To the best of our knowledge, there is no report for the cleavage of a BÀH bond with a metal-ligand bifunctional complex to give a B anion on the metal and an H cation on the ligand. [14] Here in this study, we report the first umpolung cleavage of the BÀH bond by cyclopentadienone iridium hydride complex (Figure 1 e).…”

mentioning

confidence: 99%

“…Alternatively, metal-ligand cooperative heterolytic cleavage has been attracting emerging attention in the last decade. [7][8][9] Figure 1 summarizes the representative reports for BÀH bond cleavage by metal-ligand cooperation: a) ruthenium thiolate by Ohki, Tatsumi, and Oestreich, [10] b) N,O-chelated phosphoramidate by Schafer, Love, and Weller, [11] c) palladium carbene by Iluc, [12] and d) cyclopentadienone ruthenium dimer by Casey and Clark. [13] In all of these precedents, each B À H bond is cleaved into an H anion on the metal and a B cation on the electronegative atom of the ligand, which is inheriting the polarization in the parent BÀH bonds.…”

mentioning

confidence: 99%