Exploring the Reactivity of B‐Connected Carboranylphosphines in Frustrated Lewis Pair Chemistry: A New Frame for a Classic System

Schulz, Jan; Sárosi, Menyhárt B.; Hey‐Hawkins, Evamarie

doi:10.1002/chem.202200531

Cited by 4 publications

(2 citation statements)

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“…Despite the long history of molecular H 2 activation by FLP, this chemistry remains the prospective field of research, as demonstrated in the recent perspective article by Stephan . Due to the high potential for practical applications, search for novel catalytic systems for hydrogen activation based on group 13–15 element compounds with tunable properties continues …”

Section: Introductionmentioning

confidence: 99%

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Hydrogen Activation by Frustrated and Not So Frustrated Lewis Pairs Based on Pyramidal Lewis Acid 9-Boratriptycene: A Computational Study

Pomogaeva

Timoshkin

2022

ACS Omega

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Structural features and reactivity of frustrated Lewis pairs (FLPs) formed by pyramidal group 13 Lewis acids based on 9-bora and 9-alatriptycene and bulky phosphines P t Bu 3 , PPh 3 , and PCy 3 are considered at the M06-2X/def2-TZVP level of theory. Classic FLP is formed only in the B(C 6 Me 4 ) 3 CH/P t Bu 3 system, while both FLP and donor−acceptor (DA) complex are observed in the B(C 6 F 4 ) 3 CF/P t Bu 3 system. Formation of DA complexes was observed in other systems; the B(C 6 H 4 ) 3 CH•P t Bu 3 complex features an elongated DA bond and can be considered a "latent" FLP. Transition states and reaction pathways for molecular hydrogen activation have been obtained. Processes of heterolytic hydrogen splitting are energetically more favored in solution compared to the gas phase, while activation energies in the gas phase and in solution are close. The alternative processes of hydrogenation of B−C or Al−C bonds in the source pyramidal Lewis acids in the absence of a Lewis base are exergonic but have larger activation energies than those for heterolytic hydrogen splitting. The tuning of Lewis acidity of 9-boratriptycene by changing the substituents allows one to control its reactivity with respect to hydrogen activation. Interestingly, the most promising system from the practical point of view is the DA complex B(C 6 H 4 ) 3 CH•P t Bu 3 , which is predicted to provide both low activation energy and thermodynamic reversibility of the heterolytic hydrogen splitting process. It appears that such "not so frustrated" or "latent" FLPs are the best candidates for reversible heterolytic hydrogen splitting.

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Section: Introductionmentioning

confidence: 99%

“… 8 Due to the high potential for practical applications, search for novel catalytic systems for hydrogen activation based on group 13–15 element compounds with tunable properties continues. 9 …”

Section: Introductionmentioning

confidence: 99%

Hydrogen Activation by Frustrated and Not So Frustrated Lewis Pairs Based on Pyramidal Lewis Acid 9-Boratriptycene: A Computational Study

Pomogaeva

Timoshkin

2022

ACS Omega

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Am Rande des Bekannten: Extrem elektronenreiche (Di)carboranylphosphane

et al. 2023

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Die Synthese der ersten B9‐verbundenen Carboranylphosphane (B9‐Phos) mit zwei Carboranyleinheiten sowie der Zugang zu B9‐Phos‐Liganden mit sperrigen elektronen‐schiebenden Substituenten, die bisher als unerreichbar galten, werden vorgestellt. Die elektrochemischen Eigenschaften der B9‐Phos‐Liganden wurden untersucht und die Fähigkeit der Mesityl‐Derivate, stabilisierte Phosphoniumylradikalkationen zu bilden, wurde gezeigt. Die B9‐Phos‐Liganden weisen einen extrem elektronenschiebenden Charakter auf, der den von Alkylphosphanen und allgemein verwendeten N‐heterocyclischen Carbenen übertrifft. Dies wird durch ihre sehr kleinen elektronischen Tolman‐Parameter (TEP) sowie durch extrem niedrige P−Se‐Kopplungskonstanten belegt. Kegelwinkel und verdeckten Volumina belegen die hohe sterische Hinderung, die von den (Di)carboranylphosphanen ausgeht. Die Dicarboranylphosphan‐AuI‐Komplexe zeigen im Vergleich zu den Monocarboranylphosphan‐Analoga eine bessere katalytische Leistung bei der Hydroaminierung von Alkinen.

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On the Edge of the Known: Extremely Electron‐Rich (Di)Carboranyl Phosphines

et al. 2023

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The syntheses of the first B9-connected carboranylphosphines (B9-Phos) featuring two carboranyl moieties as well as access to B9-Phos ligands with bulky electron-donating substituents, previously deemed unattainable, is reported. The electrochemical properties of the B9-Phos ligands were investigated, revealing the ability of the mesityl derivatives to form stabilized phosphoniumyl radical cations. The B9-Phos ligands display an extremely electron-releasing character surpassing that of alkyl phosphines and commonly used Nheterocyclic carbenes. This is demonstrated by their very small Tolman electronic parameters (TEPs) as well as extremely low PÀ Se coupling constants. Cone angles and buried volumes attest to the high steric demand exerted by the (di)carboranyl phosphines. The dicarboranyl phosphine Au I complexes show superior catalytic performance in the hydroamination of alkynes compared to the monocarboranyl phosphine analogs.

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Exploring the Reactivity of B‐Connected Carboranylphosphines in Frustrated Lewis Pair Chemistry: A New Frame for a Classic System

Cited by 4 publications

References 133 publications

Hydrogen Activation by Frustrated and Not So Frustrated Lewis Pairs Based on Pyramidal Lewis Acid 9-Boratriptycene: A Computational Study

Hydrogen Activation by Frustrated and Not So Frustrated Lewis Pairs Based on Pyramidal Lewis Acid 9-Boratriptycene: A Computational Study

Am Rande des Bekannten: Extrem elektronenreiche (Di)carboranylphosphane

On the Edge of the Known: Extremely Electron‐Rich (Di)Carboranyl Phosphines

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