Kai Hammond scite author profile

Homoatomic triple bonds between main-group elements have been restricted to alkynes, dinitrogen, and a handful of reactive compounds featuring trans-bent heavier elements of groups 13 and 14. Previous attempts to prepare a compound with a boron-boron triple bond that is stable at ambient temperature have been unsuccessful, despite numerous computational studies predicting their viability. We found that reduction of a bis(N-heterocyclic carbene)-stabilized tetrabromodiborane with either two or four equivalents of sodium naphthalenide, a one-electron reducing agent, yields isolable diborene and diboryne compounds. Crystallographic and spectroscopic characterization confirm that the latter is a halide-free linear system containing a boron-boron triple bond.

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Neutral zero-valent s-block complexes with strong multiple bonding

Arrowsmith

et al. 2016

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The metals of the s block of the periodic table are well known to be exceptional electron donors, and the vast majority of their molecular complexes therefore contain these metals in their fully oxidized form. Low-valent main-group compounds have recently become desirable synthetic targets owing to their interesting reactivities, sometimes on a par with those of transition-metal complexes. In this work, we used stabilizing cyclic (alkyl)(amino)carbene ligands to isolate and characterize the first neutral compounds that contain a zero-valent s-block metal, beryllium. These brightly coloured complexes display very short beryllium-carbon bond lengths and linear beryllium coordination geometries, indicative of strong multiple Be-C bonding. Structural, spectroscopic and theoretical results show that the complexes adopt a closed-shell singlet configuration with a Be(0) metal centre. The surprising stability of the molecule can be ascribed to an unusually strong three-centre two-electron π bond across the C-Be-C unit.

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Metal-free binding and coupling of carbon monoxide at a boron–boron triple bond

et al. 2013

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Many metal-containing compounds, and some metal-free compounds, will bind carbon monoxide. However, only a handful of metal-containing compounds have been shown to induce the coupling of two or more CO molecules, potentially a method for the use of CO as a one-carbon-atom building block for the synthesis of organic molecules. In this work, CO was added to a boron-boron triple bond at room temperature and atmospheric pressure, resulting in a compound into which four equivalents of CO are incorporated: a flat, bicyclic, bis(boralactone). By the controlled addition of one CO to the diboryne compound, an intermediate in the CO coupling reaction was isolated and structurally characterized. Electrochemical measurements confirm the strongly reducing nature of the diboryne compound.

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Uncatalyzed Hydrogenation of First‐Row Main Group Multiple Bonds

Arrowsmith

Böhnke

Braunschweig

et al. 2016

Chemistry A European J

104

109

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Room temperature hydrogenation of an and a CAAC-supported diboracumulene 3,5, Since the pioneering work of Sabatier over a century ago [1] catalytic hydrogenation has become the most used reaction type in industrial chemical synthesis [2] and still constitutes one of the most active research areas in chemistry. While the vast majority of industrial hydrogenation processes are based on well-established heterogeneous late transition metal catalysts (Pt, Pt, Rh, Ru, Ni) [2] the last decade has seen a revival of the field with the advent of metal-free frustrated Lewis pair catalysts capable of activating H2 [4] and transfer hydrogenation [5] for the reduction of polar multiple bonds.

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The Synthesis of B₂(SIDip)₂ and its Reactivity Between the Diboracumulenic and Diborynic Extremes

et al. 2015

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A new compound with the formula L-B2-L wherein the stabilizing ligand (L) is 1,3-bis[diisopropylphenyl]-4,5-dihydroimidazol-2-ylidene (SIDip) has been synthesized, isolated, and characterized. The π-acidity of the SIDip ligand, intermediate between the relatively non-acidic IDip (1,3-bis[diisopropylphenyl]imidazol-2-ylidene) ligand and the much more highly acidic CAAC (1-[2,6-diisopropylphenyl]-3,3,5,5-tetramethylpyrrolidin-2-ylidene) ligand, gives rise to a compound with spectroscopic, electrochemical, and structural properties between those of L-B2-L compounds stabilized by CAAC and IDip. Reactions of all three L-B2-L compounds with CO demonstrate the differences caused by their respective ligands, as the π-acidities of the CAAC and SIDip carbenes enabled the isolation of bis(boraketene) compounds (L(OC)B-B(CO)L), which could not be isolated from reactions with B2(IDip)2. However, only B2(IDip)2 and B2(SIDip)2 could be converted into bicyclic bis(boralactone) compounds.

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Kai Hammond

Ambient-Temperature Isolation of a Compound with a Boron-Boron Triple Bond

Neutral zero-valent s-block complexes with strong multiple bonding

Metal-free binding and coupling of carbon monoxide at a boron–boron triple bond

Uncatalyzed Hydrogenation of First‐Row Main Group Multiple Bonds

The Synthesis of B₂(SIDip)₂ and its Reactivity Between the Diboracumulenic and Diborynic Extremes

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Kai Hammond

Ambient-Temperature Isolation of a Compound with a Boron-Boron Triple Bond

Neutral zero-valent s-block complexes with strong multiple bonding

Metal-free binding and coupling of carbon monoxide at a boron–boron triple bond

Uncatalyzed Hydrogenation of First‐Row Main Group Multiple Bonds

The Synthesis of B2(SIDip)2 and its Reactivity Between the Diboracumulenic and Diborynic Extremes

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The Synthesis of B₂(SIDip)₂ and its Reactivity Between the Diboracumulenic and Diborynic Extremes