Readily available ascorbic acid was discovered as an environmentally benign hydrogen bond donor (HBD) for the synthesis of cyclic organic carbonates from CO2 and epoxides in the presence of nucleophilic co-catalysts. The ascorbic acid/TBAI (TBAI: tetrabutylammonium iodide) binary system could be applied for the cycloaddition of CO2 to various epoxides under ambient or mild conditions. DFT calculations and catalysis experiments revealed an intriguing bifunctional mechanism in the step of CO2 insertion involving different hydroxyl moieties (enediol, ethyldiol) of the ascorbic acid scaffold.
Combining propane dehydrogenation with propylene metathesis in a single step yields mixtures of propylene, ethylene and butenes, important building blocks for the chemical industry. The open challenges and opportunities in the field are highlighted.
Conversion of greenhouse gases to
more valuable chemicals is important
from both the environmental and industrial points of view. Herein,
the reaction mechanisms of the hydrogenation of carbon dioxide (CO2) to formic acid (HCOOH) over Cu-alkoxide-functionalized metal
organic framework (MOF) have been investigated by means of calculations
with the M06-L density functional. The reaction can proceed via two
different pathways, namely, concerted and stepwise mechanisms. In
the concerted mechanism, the hydrogenation of CO2 to formic
acid occurs in a single step. It requires a high activation energy
of 67.2 kcal/mol. For the stepwise mechanism, the reaction begins
with the hydrogen atom abstraction by CO2 to form a formate
intermediate. The intermediate then takes another hydrogen atom to
form formic acid. The activation energies are calculated to be 24.2
and 18.3 kcal/mol for the first and second steps, respectively. Because
of the smaller activation barriers associated with this pathway, it
therefore seems to be more favored than the concerted one. The catalytic
effect of Cu-MOF-5 is also highlighted by comparing it with the gas-phase
uncatalyzed reaction in which the reaction takes place in one step
with a barrier of 73.0 kcal/mol. This study also demonstrates that
the metal-functionalized MOF can be utilized for the greenhouse gas
catalysis in addition to using it to capture and activate CO2.
Catalytic conversion of hazardous gases can solve many of the environmental problems caused by them. We performed a density functional theory (DFT) study with the Perdew−Burke−Ernzerhof (PBE) functional to investigate the CO oxidation by using N 2 O as an oxidizing agent over an iron-embedded graphene (Fe-Graphene) catalyst. The N 2 O molecule was first decomposed on the Fe site yielding the N 2 molecule and an Fe−O intermediate, which was an active species for the CO oxidation. The activation energy for the N 2 O decomposition step was predicted to be 8 kcal/mol. According to the population analysis, the graphene acted as both the electron withdrawing and donating support to assist the charge transfer between the Fe atom and the probe molecules, which are important for the reaction. The reaction was found to be less facile when the Fe site was first covered by the CO which has a higher adsorption energy than that of the N 2 O (−10.0 vs −33.6 kcal/mol). The reaction proceeded via a concerted transition structure and required an activation energy of 19.2 kcal/mol when the CO was prior adsorbed. Thus, control of the adsorbing molecules over Fe-Graphene might be a key factor for the activity of the catalyst. With the higher catalytic activities of Fe-embedded graphene compared to other typical catalysts, this may open new avenues in searching for oxidation of CO at an economical cost.
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