Cyclic Carbonate Synthesis Catalysed by Bimetallic Aluminium–Salen Complexes

Clegg, William; Harrington, Ross W.; North, Michael; Pasquale, Riccardo

doi:10.1002/chem.201000030

Cited by 361 publications

(185 citation statements)

References 218 publications

(113 reference statements)

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“…One role for the tetrabutylammonium bromide is well established, 9 it acts as a bromide source to ring-open the epoxide. The induction period is consistent with the second role of tetrabutylammonium bromide being to form tributylamine in situ by a reverse Menschutkin reaction, 18 and we postulate that the tributylamine reacts with the carbon dioxide to form a carbamate salt. The adduct between a tertiary amine and carbon dioxide would normally be very unstable, but the bimetallic aluminium(salen) complex can stabilize both this and the bromo-alkoxide and allow the rate determining carbonate bond formation to occur intramolecularly rather than intermolecularly.…”

supporting

confidence: 81%

“…The aliphatic cyclohexyl and tert-butyl groups present in catalyst 1 facilitate the solubility of the catalyst in the epoxide, allowing cyclic carbonate synthesis to be carried out under solvent free conditions. Subsequent work 18 extended the range of cyclic carbonates which could be prepared using catalyst 1 and tetrabutylammonium bromide to include the three commercially most important examples (ethylene carbonate, propylene carbonate and glycerol carbonate; Scheme 2, R = H, Me, CH 2 OH respectively). Since ethylene oxide is a gas, the synthesis of ethylene carbonate was carried out in an autoclave at 6 bar carbon dioxide pressure and the synthesis of propylene carbonate was carried out at 1 bar carbon dioxide pressure but at 0 o C due to the volatility of propylene oxide.…”

Section: Catalyst Discoverymentioning

confidence: 99%

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Synthesis of cyclic carbonates from epoxides and carbon dioxide using bimetallic aluminum(salen) complexes

North¹

2012

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Over the last six years, highly active catalysts for the synthesis of cyclic carbonates from epoxides and carbon dioxide have been developed. Initial studies showed that bimetallic aluminium(salen) complexes [Al(salen)] 2 O formed active catalysts and kinetic studies allowed the catalytic cycle to be determined. The catalysts could be immobilized on silica, allowing them to be used in a gas phase flow reactor as well as in batch reactors. The compatibility of the catalysts with waste carbon dioxide present in power station flue gas has been investigated and studies to enhance the commercial applicability of the catalysts by reducing the cost of their production carried out.

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supporting

confidence: 81%

Section: Catalyst Discoverymentioning

confidence: 99%

Synthesis of cyclic carbonates from epoxides and carbon dioxide using bimetallic aluminum(salen) complexes

North¹

2012

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“…We have chosen to use MEK as the solvent because carbonyl-containing solvents allow for a higher dissolution of carbon dioxide in the reaction mixture compared with other solvent types. [36,37] It can be seen from the results listed in Table 1 that neither the co-catalyst NBu 4 I (entry 1) nor the [FeA C H T U N G T R E N N U N G (TPhOA)] 2 catalyst alone is active (entry 2). However, the combination of both the Fe complex and the co-catalyst produces an active system giving good yields of the cyclic organic carbonate product when using the iodide nucleophile, even when ambient temperatures and carbon dioxide pressures as low as 0.2 MPa (i.e., 2 bar) are used (entry 5).…”

Section: Resultsmentioning

confidence: 99%

An Efficient Iron Catalyst for the Synthesis of Five‐ and Six‐Membered Organic Carbonates under Mild Conditions

et al. 2012

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An iron(III) amine triphenolate complex, [FeTPhOA]2, able to efficiently catalyze the cycloaddition of carbon dioxide to a range of terminal epoxides under mild conditions, is described. In addition, it has also been found that the complex is able to catalyze the conversion with more sterically congested oxiranes and oxetanes which are generally considered challenging substrates to activate. Variation of the co‐catalyst, required for ring‐opening of the substrates, has also been examined. The results show that terminal epoxide substrates are converted more efficiently with an iodide co‐catalyst, whereas more bulky oxirane substrates give better product yields in the presence of a bromide co‐catalyst. The combined results demonstrate the broad applicability of these iron(III) complexes in this type of carbon dioxide fixation chemistry.

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“…[35][36][37] Shortly hereafter, the group of Kleij reported on a mononuclear Zn(salphen) complex (Figure 1; 2) active towards CO 2 coupling with terminal epoxides under moderate CO 2 pressures [p(CO 2 ) = 0.2-1 MPa] and mild operating temperatures (T = 25−45 ºC). 38,39 The high activity of the Zn(salphen) complex was ascribed to its constrained geometry imposed by the ligand scaffold, which imparts increased Lewis-acid character to the catalytically active Zn ion.…”

Section: Development Of Improved Reactivity In Coc Synthesismentioning

confidence: 99%

Recent Advances in the Catalytic Preparation of Cyclic Organic Carbonates

2015

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ABSTRACT:The catalytic formation of cyclic organic carbonates (COCs) using carbon dioxide (CO 2 ) as a renewable carbon feed stock is a highly vibrant area of research with an increasing amount of researchers focusing on this thematic investigation. These organic carbonates are highly useful building blocks and nontoxic reagents, and are most commonly derived from CO 2 coupling reactions with oxirane and di-alcohol precursors using homogeneous catalysis methodologies. The activation of suitable reaction partners using catalysis as a key technology is a requisite for efficient CO 2 conversion as its high kinetic stability poses a barrier to access functional organic molecules with added value in both academic and industrial laboratories. Though this area of science has been flourishing for at least a decade, in the last 2−3 years significant advancements have been made to address the general reactivity and selectivity issues that are associated with the formation of COCs. Here we present a concise overview of these activities with a primary focus to highlight the most important progress made and the opportunities that catalysis can bring about when the synthesis of these intermediates is optimized to a higher level of sophistication. The attention will be limited to those cases where homogeneous metal-containing systems have been employed as they possess the highest potential for directed organic synthesis using CO 2 as molecular building block. This review discusses examples of exceptional reactivity and selectivity taking into account the challenging nature of the substrates that were involved, and mechanistic understanding guiding the optimization of these protocols is also highlighted.

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Cyclic Carbonate Synthesis Catalysed by Bimetallic Aluminium–Salen Complexes

Cited by 361 publications

References 218 publications

Synthesis of cyclic carbonates from epoxides and carbon dioxide using bimetallic aluminum(salen) complexes

Synthesis of cyclic carbonates from epoxides and carbon dioxide using bimetallic aluminum(salen) complexes

An Efficient Iron Catalyst for the Synthesis of Five‐ and Six‐Membered Organic Carbonates under Mild Conditions

Recent Advances in the Catalytic Preparation of Cyclic Organic Carbonates

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