Pushing the Lewis Acidity Boundaries of Boron Compounds With Non‐Planar Triarylboranes Derived from Triptycenes

Saida, Ali Ben; Chardon, Aurélien; Osi, Arnaud; Tumanov, Nikolay; Wouters, Jan; Adjieufack, Abel Idrice; Champagne, Benoı̂t; Berionni, Guillaume

doi:10.1002/anie.201910908

Cited by 71 publications

(45 citation statements)

References 72 publications

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“…Considering that the boron pyramidalization was a key parameter, conferring to 9-boratriptycene a very high Lewis acidity, we then reasoned that switching the atom at the second bridged position of the triptycene should have a significant impact on the boron atom ground-state properties and thus deeply affect its Lewis acidic properties. 23 Accordingly, a series of 9-phosphonium-10-boratriptycene-atecomplexes was prepared by following the seminal method of Sawamura (Scheme 6). 24 A. Chardon et al…”

Section: Synpacts Synlettmentioning

confidence: 99%

“…Remarkably, the halide anion attached to the boron atom in 44-48 originated from the reaction solvent, indicating that the intermediately generated phosphonium boratriptycenes 43 abstracted a halide ion from the reaction solvent CH 2 X 2 . 23 The Lewis acidity of 43 was quantified accurately by computing its fluoride and hydride ion affinities and comparing them with those of other cationic Lewis acids (Figure 8). 25 The fluoride ion affinity (FIA) of the catechol borenium ion 53 26 substantially surpassed that of 43 and 52, showing that the highly pyramidalized boron atom in addi-…”

Section: Scheme 7 Protodeboronation Of 38 By Using Hbf 4 and Hntfmentioning

confidence: 99%

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Non-planar Boron Lewis Acids Taking the Next Step: Development of Tunable Lewis Acids, Lewis Superacids and Bifunctional Catalysts

Chardon

Osi²,

Mahaut³

et al. 2020

Synlett

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Although boron Lewis acids commonly adopt a trigonal planar geometry, a number of compounds in which the trivalent boron atom is located in a pyramidal environment have been described. This review will highlight the recent developments of the chemistry and applications of non-planar boron Lewis acids, including a series of non-planar triarylboranes derived from the triptycene core. A thorough analysis of the properties and of the influence of the pyramidalization of boron Lewis acids on their stereoelectronic properties and reactivities is presented based on recent theoretical and experimental studies.1 Non-planar Trialkylboranes2 Non-planar Alkyl and Aryl-Boronates3 Non-planar Triarylboranes and Alkenylboranes3.1 Previous Investigations on Bora Barrelenes and Triptycenes3.2 Recent Work on Boratriptycenes from Our Research Group4 Applications of Non-planar Boranes4.1 Non-planar Alkyl Boranes and Boronates4.2 Non-planar Triarylboranes (Boratriptycenes)5 Other Non-planar Group 13 Lewis Acids6 Further Work and Perspectives

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Section: Synpacts Synlettmentioning

confidence: 99%

Section: Scheme 7 Protodeboronation Of 38 By Using Hbf 4 and Hntfmentioning

confidence: 99%

Non-planar Boron Lewis Acids Taking the Next Step: Development of Tunable Lewis Acids, Lewis Superacids and Bifunctional Catalysts

Chardon

Osi²,

Mahaut³

et al. 2020

Synlett

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“…In an effort to access 9‐boratriptycene derivatives, we recently developed a method to generate the strongly pyramidalized 9‐bora‐10‐phosphatriptycene 8 as a transient Lewis acid with exceptionally high Lewis acidity (Scheme a) . Though the protodeboronation of 10 proceeded selectively at the exocyclic C−B bond (Scheme a), disappointingly, protodeboronation of the 9‐phenyl‐boratriptycene ate complex 13 lacking a phosphonium bridge occurred at an intracyclic C−B bond, thus preventing the formation of 9‐boratriptycene 9 (Scheme b) …”

Section: Methodsmentioning

confidence: 99%

Controlled Generation of 9‐Boratriptycene by Lewis Adduct Dissociation: Accessing a Non‐Planar Triarylborane

et al. 2020

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A highly bent triarylborane, 9‐boratriptycene, was generated in solution by selective protodeboronation of the corresponding tetra‐aryl boron ate complex with the strong Brønsted acid HNTf2. The iptycene core confers enhanced Lewis acidity to 9‐boratriptycene, making it unique in terms of structure and reactivity. We studied the stereoelectronic properties of 9‐boratriptycene by quantifying its association with small N‐ and O‐centered Lewis bases, as well as with sterically hindered phosphines. The resultant Lewis adducts exhibited unique structural, spectroscopic, and photophysical properties. Beyond the high pyramidalization of the 9‐boratriptycene scaffold and its low reorganization energy upon Lewis base coordination, quantum chemical calculations revealed that the absence of π donation from the triptycene aryl rings to the boron vacant pz orbital is one of the main reasons for its high Lewis acidity.

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“…For example, constraining molecular planarity using tethers leads to a reduced Lewis acidity of boron (31 a-b; Scheme 36a), whereas incorporating boron into cage-like molecules gave enhanced Lewis acidity (31 e; Scheme 36a). [49] The increased Lewis acidity of boron in 31 e is because of the preorganized pyramidal geometry, which not only provides a vacant sp 3 orbital directed ideally to accept the fourth electron-donating ligand but also allow geometry reorganization with minimal energy barrier (Scheme 36b). Therefore, there have been several efforts to isolate non-VSEPR structures of group-13 compounds for exploring the structurereactivity relationships.…”

Section: Geometry Constrained Group 13 Compoundsmentioning

confidence: 99%

Pincer‐Type Ligand‐Assisted Catalysis and Small‐Molecule Activation by non‐VSEPR Main‐Group Compounds

Kundu

2020

Chemistry An Asian Journal

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Pushing the Lewis Acidity Boundaries of Boron Compounds With Non‐Planar Triarylboranes Derived from Triptycenes

Cited by 71 publications

References 72 publications

Non-planar Boron Lewis Acids Taking the Next Step: Development of Tunable Lewis Acids, Lewis Superacids and Bifunctional Catalysts

Non-planar Boron Lewis Acids Taking the Next Step: Development of Tunable Lewis Acids, Lewis Superacids and Bifunctional Catalysts

Controlled Generation of 9‐Boratriptycene by Lewis Adduct Dissociation: Accessing a Non‐Planar Triarylborane

Pincer‐Type Ligand‐Assisted Catalysis and Small‐Molecule Activation by non‐VSEPR Main‐Group Compounds

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