Phosphine‐Stabilized Borylenes and Boryl Anions as Ligands? Redox Reactivity in Boron‐Based Pincer Complexes

The electronic structure of (η -Cp) Zr(NH -BB-NH ) (3 b) suggests that it could be a candidate for having a boron-boron triple bond in the cyclic system; however, computational studies shows that 3 b is a very high energy isomer on its potential energy surface. Replacement of amines with tricoordinate nucleophilic boron groups (η -Cp) Zr[B(PH ) -BB-B(PH ) ] (3 c) reduces the relative energy dramatically. The B≡B triple bond arises through the donation of two electrons from the metal fragment, ZrCp , to the in-plane π-bonding orbital of the central B-B unit. Strong σ-donating and chelating bis-phosphine ligands (Me P(CH ) PMe ), which stabilize donor-acceptor bonding interaction in gem-diborene L B-BBr (10), would be a good choice along the synthetic path towards 3 d, (η -Cp) Zr[B (Me P(CH ) PMe ) ]. A comparison of the energetics of the reaction leading to a cyclic boryne system (3 d), with the linear boryne isomer [(B NHC ) ] shows that the angle strain from cyclization is compensated by stabilization from the metal.

Section: Methodsmentioning

confidence: 98%

“…This is yet another confirmation of higher nucleophilicity of the boron center induced by PH 3 . The recent realization of bis‐phosphine stabilized borylene system (Figure S8 in the Supporting Information) strongly suggests that 3 c would be a promising target for synthetic efforts …”

Section: Methodsmentioning

confidence: 99%

A DFT Study on the Stabilization of the B≡B Triple Bond in a Metallaborocycle: Contrasting Electronic Structures of Boron and Carbon Analogues

Ghorai

Jemmis

2017

“…In a recent study, we reported the formation of PBP‐type pincer complexes through dehydrogenative P−B bond formation of phosphine‐borane complexes . In continuation of this work, we investigated the reactivity of other metal precursors in these P−B bond‐forming reactions.…”

Section: Resultsmentioning

confidence: 99%

“…In addition to the metal oxidation state and the nature of the ancillary ligands, the substituents at the boron atom seem to be essential for the observed reactivity patterns. For N‐ and C‐based substituents at boron, hydride‐transfer and dihydrogen elimination are observed between the metal and the ligand,,, whereas for phosphine substituents, a pronounced redox reactivity between the metal and boron atom takes place …”

Section: Introductionmentioning

confidence: 99%

Ambireactive (R₃P)₂BH₂ Groups Facilitating Temperature‐Switchable Bond Activation by an Iron Complex

Vondung

Sattler

Langer

2017

Self Cite

An iron pincer complex containing a hemi-labile (R P) BH group exhibits temperature-switchable reactivity patterns: a reversible B-H activation concomitant with a P-B bond cleavage is observed at room temperature. Below 4 °C, intra- and intermolecular C-H activation pathways are becoming faster and more dominant. Mechanistic investigations reveal that the lability of the (R P) BH group in combination with the exothermic formation of σ-bonded complexes are responsible for the switchable bond activation. Finally, a protocol for an iron-catalyzed H/D-exchange of organic solvents in the absence of oxidants has been developed.

“…However, the further degradation of boryl intermediates such as C to complexes with a boron‐based donor ligand ( D ) has not been considered to be a viable mechanistic scenario so far. Recently, we reported the formation of an iron complex with such a phosphine‐stabilized borylene as ligand (type D ) and provided evidence for pathway A → D . Although the reactivity of transition metal boryl and borylene complexes has been discussed extensively, examples of base‐stabilized borylenes and their transition metal complexes are still rare .…”

Section: Introductionmentioning

confidence: 99%

Umpolung at Boron: Ancillary‐Ligand‐Induced Formation of Boron‐Based Donor Ligands from Phosphine‐Boranes

Vondung

Alig

Ballmann

et al. 2018

Self Cite

Easy-to-prepare η -coordinated phosphine-borane ligands are demonstrated to liberate hydrogen upon treatment with different σ-donor/π-acceptor ligands (CO, tBuNC, CN ). Depending on the utilized ancillary ligand, different reaction pathways are observed, ranging from simple hydride protonation to iron-boron bond formation and subsequent rearrangement to pincer-type ligands based on a tricoordinate boron centre. The last-named reactivity is in line with a formal umpolung at the boron centre from a Lewis acidic borane to a Lewis basic boron-based donor ligand.