N-Heterocyclic carbene functionalized MCM-41 as an efficient catalyst for chemical fixation of carbon dioxide

“…At a later stage, the same group has shown that a NHC-CO 2 adduct could also be immobilized on a MCM-41 support and the catalytic activity of this hybrid material in the coupling between CO 2 and epoxides was investigated. 64 Although applicable, these protocols based on NHC catalysts and their corresponding derivatives require high CO 2 pressures (> 20 bar) and temperatures (> 100 o C). The hybrid silica material is indeed recyclable; however, its multi-step synthesis and isolation may result in extra energy and cost consumption, compromising to some extend the overall process sustainability.…”

“…When NHC scaffolds (Scheme 3; R 1 = i-Pr, R 2 = H) were grafted onto a silica MCM-41 support, the resultant catalyst was active towards cyclic carbonate formation at 0.5 mol % catalyst loading under relatively mild conditions (T = 120 ºC, p(CO 2 ) = 20 bar, t = 24−48 h), whereas this supported catalyst was also used for the synthesis of oxazolidinones under even milder conditions (T = 80-100 ºC) affording N-substituted oxazolidinones in excellent yields. 64 A different NHC (R 1 = 2,6(i-Pr) 2 C 6 H 5 ; R 2 = H) was covalently embedded within a tubular, micro-porous organic network. When using this heterogeneous catalytic system, propylene oxide (PO) was quantitatively converted to propylene carbonate in 10 h with a catalyst load of only 0.065 mol % (Yield = 92%; TOF = 142 s -1 , T = 160 ºC, p(CO 2 ) = 30 bar).…”

Sustainable conversion of carbon dioxide: the advent of organocatalysis

“…At a later stage, the same group has shown that a NHC-CO 2 adduct could also be immobilized on a MCM-41 support and the catalytic activity of this hybrid material in the coupling between CO 2 and epoxides was investigated. 64 Although applicable, these protocols based on NHC catalysts and their corresponding derivatives require high CO 2 pressures (> 20 bar) and temperatures (> 100 o C). The hybrid silica material is indeed recyclable; however, its multi-step synthesis and isolation may result in extra energy and cost consumption, compromising to some extend the overall process sustainability.…”

“…When NHC scaffolds (Scheme 3; R 1 = i-Pr, R 2 = H) were grafted onto a silica MCM-41 support, the resultant catalyst was active towards cyclic carbonate formation at 0.5 mol % catalyst loading under relatively mild conditions (T = 120 ºC, p(CO 2 ) = 20 bar, t = 24−48 h), whereas this supported catalyst was also used for the synthesis of oxazolidinones under even milder conditions (T = 80-100 ºC) affording N-substituted oxazolidinones in excellent yields. 64 A different NHC (R 1 = 2,6(i-Pr) 2 C 6 H 5 ; R 2 = H) was covalently embedded within a tubular, micro-porous organic network. When using this heterogeneous catalytic system, propylene oxide (PO) was quantitatively converted to propylene carbonate in 10 h with a catalyst load of only 0.065 mol % (Yield = 92%; TOF = 142 s -1 , T = 160 ºC, p(CO 2 ) = 30 bar).…”

Sustainable conversion of carbon dioxide: the advent of organocatalysis

“…Under the conditions of 1 atm CO 2 and 60°C, the epichlorohydrin substrate displays a good applicability for co-catalysts, that is, a high reactivity was obtained when coupled with most of the investigated co-catalysts (Table 2). In the previous studies [7,32], N-heterocyclic compounds were often applied to the conversion of CO 2 to cyclic carbonates due to the presence of nucleophilic sites. In our work, several N-heterocyclic compounds were also examined as possible co-catalyst, and an activity order was obtained with DMAP > IM > DBU > Py (entries 10-11, 13-14, Table 2), which is related to their nucleophilic and basic strength [23,33,34].…”

Highly efficient conversion of CO2 at atmospheric pressure to cyclic carbonates with in situ-generated homogeneous catalysts from a copper-containing coordination polymer

“…In the past few decades, the numerous heterogeneous and homogeneous catalysts have been developed for the synthesis of cyclic carbonates from epoxides and CO 2 [30][31][32] -such as metal oxides [33], molecular sieves [34], ion-exchange resins [35], nanoparticles [36], alkali metal salts [37], quaternary ammonium salts [38][39][40], transition metal complexes [41][42][43][44], metal-organic frameworks [45], N-heterocyclic carbenes [46], Lewis acids or bases [47,48], ionic liquid [49][50][51][52][53], and so on. Among these catalysts, ionic liquids have been shown to have excellent activity in the synthesis of cyclic carbonates from carbon dioxide and epoxides.…”

A heteropolyacid-based ionic liquid immobilized onto Fe3O4/SiO2/Salen/Mn as an environmentally friendly catalyst for synthesis of cyclic carbonate