Reductive Cyclotrimerization of Carbon Monoxide to the Deltate Dianion by an Organometallic Uranium Complex

Summerscales, Owen T.; Cloke, F. Geoffrey N.; Hitchcock, Peter B.; Green, Jennifer C.; Hazari, Nilay

doi:10.1126/science.1121784

Cited by 274 publications

(211 citation statements)

References 16 publications

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“…The high reduction potentials of low valent f-element complexes suggests a promising approach for the reductive activation of C 1 -small molecules such as CO (19)(20)(21)(22) and CO 2 (23); however, only a handful of f-element complexes can affect the reductive homologation of CO under ambient conditions (24,25). Organometallic uranium complexes can effect reductive homologation of CO to C n -oligomers (n ¼ 2-4) (26)(27)(28), and a small number of uranium triamide and triaryloxide complexes also reductively dimerize CO (29,30). More recently, an organometallic uranium complex was shown to effect the simultaneous reduction and hydrogenation of CO to give a coordinated methoxide that could be liberated as CH 3 OSiMe 3 (31); however, there have been no reports of successful homologation, functionalization, and removal of C n -oligomers (n ≥ 2) under mild conditions with retention of a metal complex that may be recycled for reuse in a synthetic cycle as has been demonstrated for CO 2 (32, 33), P 4 (34), and carbodiimides (35).…”

mentioning

confidence: 99%

Homologation and functionalization of carbon monoxide by a recyclable uranium complex

Gardner

Stewart

Davis

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

156

107

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Carbon monoxide (CO) is in principle an excellent resource from which to produce industrial hydrocarbon feedstocks as alternatives to crude oil; however, CO has proven remarkably resistant to selective homologation, and the few complexes that can effect this transformation cannot be recycled because liberation of the homologated product destroys the complexes or they are substitutionally inert. Here, we show that under mild conditions a simple triamidoamine uranium(III) complex can reductively homologate CO and be recycled for reuse. Following treatment with organosilyl halides, bis(organosiloxy)acetylenes, which readily convert to furanones, are produced, and this was confirmed by the use of isotopically 13 C-labeled CO. The precursor to the triamido uranium(III) complex is formed concomitantly. These findings establish that, under appropriate conditions, uranium(III) can mediate a complete synthetic cycle for the homologation of CO to higher derivatives. This work may prove useful in spurring wider efforts in CO homologation, and the simplicity of this system suggests that catalytic CO functionalization may soon be within reach.reduction | C-C coupling | ethyne diolate | antiferromagnetic exchange coupling T he continued growth and stability of the global economy requires the ready availability of petrochemical feedstocks, but uncertainty in cost and supply, underscored by the energy crisis in the 1970s, has driven the demand for developing alternative sources (1). CO is readily produced by steam reforming reactions and is, thus, an abundant resource that can be used in the production of bulk hydrocarbon feedstocks (2). The concept of directly homologating CO is very appealing, but the triple bond in CO is very strong with a bond energy of ∼257 kcal mol −1 , and direct dimerization of CO to O ¼ C ¼ C ¼ O is highly unfavorable with ΔG°2 98 K ≈ þ73 kcal mol −1 (3). Although direct 1,1-migratory insertion of CO into an organometallic M-R bond to give M-C(O)R is a favorable process for many metals (4) and a key step in industrially important C-C bond formation reactions, e.g., hydroformylation (5), double insertion to give M-C(O)C(O)R is usually energetically unfeasible, but it has been documented (6-8). Thus, processes involving CO can require energy intensive reaction conditions and give varied product distributions that render them economically uncompetitive overall when crude oil remains readily available; however, combining the coupling of CO with reduction results in a thermodynamically feasible process to give a family of oxocarbon dianions C n O n 2− (n ¼ 2-6), including the reductively dimerized ethyne diolate − O-C ≡ C-O − , as building blocks for more complex and value-added organic molecules (9).Molten potassium can effect reductive oligomerization of CO, but the resulting ill-defined salts are thermally unstable and shock-sensitive (10). CO can be electrochemically homologated, but an overpressure of 100-400 bar of CO is required (11). Very few transition metal complexes mediate the reductive coupling...

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confidence: 99%

Homologation and functionalization of carbon monoxide by a recyclable uranium complex

Gardner

Stewart

Davis

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

156

107

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“…The distances between the metal and the ring centroids in the U(h-C 8 H 6 {SiiPr 3 -1,4} 2 )(hCp*) fragment (U-M1 2.4887(2) and U-M2 1.95590(2) ) are identical within the estimated standard deviations (esds) to those for other U IV complexes incorporating this fragment, for example, [U(h-C 8 H 6 {SiiPr 3 -1,4} 2 )(h-Cp*)] 2 (m-h 1 :h 2 -C 3 O 3 ) (U-M1 2.480(8) and U-M2 1.950 (8) ), although the M1-U- M2 angle in 3 (135.809 (9)8) is slightly more acute than that in the latter (141.8 (2)8). [6] The U-OMe linkage in 3 is essentially linear (178.3 (5)8) with a U-O distance of 2.058(4) , and the structural features are comparable to those found in other (rare) examples of U IV terminal methoxide complexes. [10] To gain insight into the bonding situation in 3, computational studies were carried out at the DFT (B3PW91/SDD-(U,Si)-6-31G(d,p)(C,O,H)) level.…”

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confidence: 65%

Facile Conversion of CO/H₂ into Methoxide at a Uranium(III) Center

et al. 2011

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“…[3] Neueste Befunde lassen außerdem vermuten, dass Uran ein geeigneter Promotor im Fischer-Tropsch-Verfahren sein kçnnte, in dem CO und H 2 zu flüssigen Kohlenwasserstoffen umgewandelt werden. [1,[4][5][6][7] Trotz des offensichtlichen Potenzials von Uran sind Reaktionen der f-Elemente mit CO, vor allem verglichen mit denen der Übergangsmetalle, nur unzureichend erforscht. Diese Tatsache dürfte auf die schwachen p-Rückbindungen in Komplexen der f-Elemente zurückzuführen sein.…”

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“…[13] Das quadratisch-planare SquaratDianion (Abbildung 1, C) kann elektrochemisch bei sehr hohem CO-Druck erzeugt werden. [14] Bis 2006 war die Synthese des trigonalen Deltat-Dianions (Abbildung 1, B) [4] Geringe sterische Veränderungen im Ligandensystem ermçglichten die Isolierung eines cyclotetramerisierten Produkts in Form eines über ein C 4 O 4 2À -Quadrat verbrückten Urankomplexes. [5] Der Mechanismus dieser Reaktion verläuft vermutlich über ein relativ langlebiges "Zickzack"-Intermediat, U-C 2 O 2 -U, das mit CO weiterreagiert (Schema 1).…”

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Hydrierung von CO an einem Uran(III)‐Zentrum

Lam

Meyer

2011

Angewandte Chemie

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Reductive Cyclotrimerization of Carbon Monoxide to the Deltate Dianion by an Organometallic Uranium Complex

Cited by 274 publications

References 16 publications

Homologation and functionalization of carbon monoxide by a recyclable uranium complex

Homologation and functionalization of carbon monoxide by a recyclable uranium complex

Facile Conversion of CO/H₂ into Methoxide at a Uranium(III) Center

Hydrierung von CO an einem Uran(III)‐Zentrum

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Reductive Cyclotrimerization of Carbon Monoxide to the Deltate Dianion by an Organometallic Uranium Complex

Cited by 274 publications

References 16 publications

Homologation and functionalization of carbon monoxide by a recyclable uranium complex

Homologation and functionalization of carbon monoxide by a recyclable uranium complex

Facile Conversion of CO/H2 into Methoxide at a Uranium(III) Center

Hydrierung von CO an einem Uran(III)‐Zentrum

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Facile Conversion of CO/H₂ into Methoxide at a Uranium(III) Center