Boosting Low‐Valent Aluminum(I) Reactivity with a Potassium Reagent

Grams, Samuel; Eyselein, Jonathan; Langer, Jens; Färber, Christian; Harder, Sjoerd

doi:10.1002/ange.202006693

Cited by 54 publications

(20 citation statements)

References 55 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Harder modeled the reaction highlighting the role of potassium cations through favorable noncovalent interactions. [32] Fernandez et al computed the CÀ H activation in toluene using the naked version of complex IV and its potassium stabilized version. [29] The authors presented quantitative evidence of a synergy effect of the potassium atoms through the whole reaction path by attractive dispersion interactions, producing a decrease of 3.9 kcal mol À 1 in the rate-limiting step encompassing the S N Ar mechanism.…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, K + atoms play an essential role in the stabilization of the Meisenheimer intermediate, reinforcing the idea of including the cations in the calculation. [29,32] On the other hand, Yamashita et al reported the first example of a potassium-dialkylaluminium salt. Although the prepared system demonstrated its strong basicity and electrophilic character by reacting with benzene, MeOTf, benzyl chloride, and C 6 F 6 , prominent substrate⋯interactions were observed for C 6 H 6 and benzyl chloride (C 6 F 6 to a minor extend).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Contrasting the Mechanism of H₂Activation by Monomeric and Potassium‐Stabilized Dimeric Al^IComplexes: Do Potassium Atoms Exert any Cooperative Effect?

Villegas‐Escobar

Toro–Labbé

Schaefer

2021

Chemistry A European J

View full text Add to dashboard Cite

Aluminyl anions are low-valent, anionic, and carbenoid aluminum species commonly found stabilized with potassium cations from the reaction of Al-halogen precursors and alkali compounds. These systems are very reactive toward the activation of σ-bonds and in reactions with electrophiles. Various research groups have detected that the potassium atoms play a stabilization role via electrostatic and cation� � � p interactions with nearby (aromatic)-carbocyclic rings from both the ligand and from the reaction with unsaturated substrates. Since stabilizing K⋯H bonds are witnessed in the activation of this class of molecules, we aim to unveil the role of these metals in the activation of the smaller and less polarizable H 2 molecule, together with a comprehensive characterization of the reaction mechanism. In this work, the activation of H 2 utilizing a NON-xanthene-Al dimer, [K{Al-(NON)}] 2 (D) and monomeric, [Al(NON)] À (M) complexes are studied using density functional theory and high-level coupled-cluster theory to reveal the potential role of K + atoms during the activation of this gas. Furthermore, we aim to reveal whether D is more reactive than M (or vice versa), or if complicity between the two monomer units exits within the D complex toward the activation of H 2 . The results suggest that activation energies using the dimeric and monomeric complexes were found to be very close (around 33 kcal mol À 1 ). However, a partition of activation energies unveiled that the nature of the energy barriers for the monomeric and dimeric complexes are inherently different. The former is dominated by a more substantial distortion of the reactants (and increased interaction energies between them). Interestingly, during the oxidative addition, the distortion of the Al complex is minimal, while H 2 distorts the most, usually over 0.77 DE 6 ¼ dist . Overall, it is found here that electrostatic and induction energies between the complexes and H 2 are the main stabilizing components up to the respective transition states. The results suggest that the K + atoms act as stabilizers of the dimeric structure, and their cooperative role on the reaction mechanism may be negligible, acting as mere spectators in the activation of H 2 . Cooperation between the two monomers in D is lacking, and therefore the subsequent activation of H 2 is wholly disengaged.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Contrasting the Mechanism of H₂Activation by Monomeric and Potassium‐Stabilized Dimeric Al^IComplexes: Do Potassium Atoms Exert any Cooperative Effect?

Villegas‐Escobar

Toro–Labbé

Schaefer

2021

Chemistry A European J

View full text Add to dashboard Cite

show abstract

“…[27] Subsequently,t wo further potassium aluminyl complexes featuring bidentate diamido ligands have been reported. [28] Thefirst of these,K 2 [Al( Si NON)] 2 (7), was reported by Coles and co-workers in 2019, [29] and more recently K 2 [Al(NCCN)] 2 (8)w as reported by Hill, McMullin and co-workers in 2020 ( Figure 3). [30] Both of these complexes were synthesised using as imilar synthetic route to 6,t hat is,b yt he two-electron reduction of the corresponding aluminium(III) iodide precursor with potassium.…”

Section: Anionic Group 13 Centred Nucleophilesmentioning

confidence: 69%

The Aluminyl Anion: A New Generation of Aluminium Nucleophile

et al. 2020

View full text Add to dashboard Cite

Trivalent aluminium compounds are well known for their reactivity as Lewis acids/electrophiles, a feature that is exploited in many pharmaceutical, industrial and laboratory‐based reactions. Recently, a series of isolable aluminium(I) anions (“aluminyls”) have been reported, which offer an alternative to this textbook description: these reagents behave as aluminium nucleophiles. This minireview covers the synthesis, structure and reactivity of aluminyl species reported to date, together with their associated metal complexes. The frontier orbitals of each of these species have been investigated using a common methodology to allow for a like‐for‐like comparison of their electronic structure and a means of rationalising (sometimes unprecedented) patterns of reactivity.

show abstract

“…Later, other examples without O-donor moieties or even N-substituents were reported by Yamashita, Kinjo, Coles, Harder and Hill. [9][10][11][12][13] Braunschweig and coworkers utilised a bulky cyclopentadienyl derivative to stabilise the monomeric Al(I) compound E. 14 The quest for a genuine monocoordinated Al(I) compound was still to be tackled. The group of Power was the first to succeed when they employed the bulkiest terphenyl substituent available and prepared the alanediyl F. 15,16 Scheme 1.…”

mentioning

confidence: 99%

Attempted reduction of a carbazolyl-diiodoalane

Hinz

Müller

2021

Chem. Commun.

View full text Add to dashboard Cite

show abstract

Boosting Low‐Valent Aluminum(I) Reactivity with a Potassium Reagent

Cited by 54 publications

References 55 publications

Contrasting the Mechanism of H₂Activation by Monomeric and Potassium‐Stabilized Dimeric Al^IComplexes: Do Potassium Atoms Exert any Cooperative Effect?

Contrasting the Mechanism of H₂Activation by Monomeric and Potassium‐Stabilized Dimeric Al^IComplexes: Do Potassium Atoms Exert any Cooperative Effect?

The Aluminyl Anion: A New Generation of Aluminium Nucleophile

Attempted reduction of a carbazolyl-diiodoalane

Contact Info

Product

Resources

About

Boosting Low‐Valent Aluminum(I) Reactivity with a Potassium Reagent

Cited by 54 publications

References 55 publications

Contrasting the Mechanism of H2Activation by Monomeric and Potassium‐Stabilized Dimeric AlIComplexes: Do Potassium Atoms Exert any Cooperative Effect?

Contrasting the Mechanism of H2Activation by Monomeric and Potassium‐Stabilized Dimeric AlIComplexes: Do Potassium Atoms Exert any Cooperative Effect?

The Aluminyl Anion: A New Generation of Aluminium Nucleophile

Attempted reduction of a carbazolyl-diiodoalane

Contact Info

Product

Resources

About

Contrasting the Mechanism of H₂Activation by Monomeric and Potassium‐Stabilized Dimeric Al^IComplexes: Do Potassium Atoms Exert any Cooperative Effect?

Contrasting the Mechanism of H₂Activation by Monomeric and Potassium‐Stabilized Dimeric Al^IComplexes: Do Potassium Atoms Exert any Cooperative Effect?