Direct CO<sub>2</sub> Transformation to Aliphatic Polycarbonates

Tamura, Masazumi; Nakagawa, Yoshinao; Tomishige, Keiichi

doi:10.1002/ajoc.202200445

Cited by 19 publications

(11 citation statements)

References 100 publications

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“…Meanwhile, under the “stoichiometric” (alcohol/nitrile/CH 3 CN=50 : 25 : 100) and “alcohol‐excess” (100 : 25 : 100) conditions, the possible maximum amount of dialkyl carbonates is 25 mmol. Under these three conditions, we conducted the reactions using two different amounts of CeO 2 catalyst (0.17 g and 0.68 g), which and whose related materials have been reported by many research groups to exhibit good catalytic activity for non‐reductive conversion of CO 2 [4,21–27,34–57] . The results obtained with the smaller amount of CeO 2 catalyst (0.17 g) are reflected by the reactivity of alcohols and nitrile dehydrants over the catalyst surfaces, and those with the larger amount of CeO 2 (0.68 g) provide the information about the saturation level of the product formation.…”

Section: Resultsmentioning

confidence: 99%

Comparative Study between 2‐Furonitrile and 2‐Cyanopyridine as Dehydrants in Direct Synthesis of Dialkyl Carbonates from CO₂ and Alcohols over Cerium Oxide Catalyst

Sun,

Li,

Yabushita

et al. 2023

ChemSusChem

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The shift of equilibrium by removing water with nitrile dehydrants is crucial for CeO2‐catalyzed synthesis of dialkyl carbonates from CO2 and alcohols. Two nitriles – 2‐cyanopyridine and 2‐furonitrile – were previously found as effective dehydrants, yet their detailed comparison as well as exploration of potential of 2‐furonitrile remain insufficient. Herein, the performance of 2‐cyanopyridine and 2‐furonitrile was compared in the synthesis of various dialkyl carbonates. 2‐furonitrile was found to be superior to 2‐cyanopyridine in the synthesis of dialkyl carbonates from CO2 and bulky or long‐chain (≥C3) alcohols. Namely, the yield of diisopropyl carbonate (up to 50 %) achieved using CeO2 and 2‐furonitrile is comparable to or even higher than previously reported ones. Meanwhile, 2‐cyanopyridine acted as a better dehydrant than 2‐furonitrile in the synthesis of dimethyl carbonate and diethyl carbonate. The adsorption experiments and density functional theory calculations have indicated that the better performance of 2‐furonitrile compared to 2‐cyanopyridine in the synthesis of dialkyl carbonates from bulky or long‐chain alcohols is due to the weaker interaction of 2‐furonitrile with the CeO2 surface. Such weak interaction of 2‐furonitrile offers a larger reaction field on the catalyst surface for both CO2 and alcohols.

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Section: Resultsmentioning

confidence: 99%

Comparative Study between 2‐Furonitrile and 2‐Cyanopyridine as Dehydrants in Direct Synthesis of Dialkyl Carbonates from CO₂ and Alcohols over Cerium Oxide Catalyst

Sun,

Li,

Yabushita

et al. 2023

ChemSusChem

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“…Initially, aPCs were synthesized by following the same method as employed for aromatic polycarbonates viz. condensation of aliphatic diols with toxic phosgene gas [1,19] . The main drawback of this method is the use of highly toxic reagents and the high dispersity associated with the resulting polycarbonates [1] .…”

Section: Synthesis Methods Of Apcsmentioning

confidence: 99%

“…condensation of aliphatic diols with toxic phosgene gas. [1,19] The main drawback of this method is the use of highly toxic reagents and the high dispersity associated with the resulting polycarbonates. [1] This approach was slightly modified by doing a two-step melt reaction between aliphatic diols and dialkyl carbonate, which entails an initial condensation to form oligomers and a subsequent transesterification or carbonate metathesis in the presence of catalysts.…”

Section: Polycondensationmentioning

confidence: 99%

Enabling New Approaches: Recent Advances in Processing Aliphatic Polycarbonate‐Based Materials

Wei,

Bhat,

Darensbourg

2023

Angew Chem Int Ed

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Aliphatic polycarbonates (aPCs) have become increasingly popular as functional materials due to their biocompatibility and capacity for on‐demand degradation. Advances in polymerization techniques and the introduction of new functional monomers have expanded the library of aPCs available, offering a diverse range of chemical compositions and structures. To accommodate the emerging requirements of new applications in biomedical and energy‐related fields, various manufacturing techniques have been adopted for processing aPC‐based materials. However, a summary of these techniques has yet to be conducted. The aim of this paper is to enrich the toolbox available to researchers, enabling them to select the most suitable technique for their materials. In this paper, a concise review of the recent progress in processing techniques, including controlled self‐assembly, electrospinning, additive manufacturing, and other techniques, is presented. We also highlight the specific challenges and opportunities for the sustainable growth of this research area and the successful integration of aPCs in industrial applications.

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“…As an alternative, CO 2 capture and utilization have received much attention, as CO 2 can be used to produce high-value chemicals via chemical transformation or electrocatalytic, , photocatalytic, , and photothermocatalytic processes. In this regard, CO 2 has been used as a C 1 building block to produce value-added chemicals (carbon monoxide, methanol, formic acid, formaldehyde, acetic acid, and acetaldehyde), high-energy-density fuels (methane, propane, and ethanol), and precursors for polymers such as ethylene and carbonate . Production of liquid electro-fuels (e-fuels) derived from CO 2 , to substitute fossil fuel is vital to reaching a net-zero carbon footprint.…”

Section: Introductionmentioning

confidence: 99%

“…In this regard, CO 2 has been used as a C 1 building block to produce value-added chemicals (carbon monoxide, methanol, formic acid, formaldehyde, acetic acid, and acetaldehyde), high-energy-density fuels (methane, propane, and ethanol), and precursors for polymers such as ethylene 8 and carbonate. 9 Production of liquid electro-fuels (e-fuels) derived from CO 2 , 10 to substitute fossil fuel is vital to reaching a net-zero carbon footprint. In addition, CO 2 can be used for the functionalization of organic compounds through photo-and electrocatalytic carboxylation reactions.…”

Section: Introductionmentioning

confidence: 99%

Rational Design of Heterogeneous Dual-Atom Catalysts for CO₂ Electroreduction Reactions

Jafarzadeh

Daasbjerg

2023

ACS Appl. Energy Mater.

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One of the strategies to mitigate the concentration of CO 2 in the atmosphere and reduce the global warming effect is to capture CO 2 and convert it to synthetic fuels and fine chemicals. Although CO 2 is structurally and chemically stable, the electrochemical transformation has attracted much attention because it offers mild reaction conditions regarding temperature, pressure, and process controllability. Among various electrocatalysts, dualatom catalysts (DACs) have been extensively developed in the past few years due to their unique features for the electrochemical reactions of small molecules. The catalytic activity of DACs in the electrochemical CO 2 reduction reaction (eCO 2 RR) has surpassed single-atom catalysts (SACs) by providing a higher metal loading, two active sites (cf. one active site for SACs), a synergistic effect of adjacent metal atoms, the possibility of tuning the electronic state (adjusting the d-band center), and more possible configuration modes (side-on and side-bridge) for adsorption of CO 2 (cf. only end-on and end-bridge modes for SACs). As a result, both higher reactivity and selectivity in eCO 2 RR can be achieved by breaking scaling relationships with more possible interactions between intermediates and active sites. This review highlights and discusses the recent progress in applying homo-and heteronuclear DACs for eCO 2 RR focusing on the synthesis, characterization, and electrochemical catalytic performance.

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Direct CO₂ Transformation to Aliphatic Polycarbonates

Cited by 19 publications

References 100 publications

Comparative Study between 2‐Furonitrile and 2‐Cyanopyridine as Dehydrants in Direct Synthesis of Dialkyl Carbonates from CO₂ and Alcohols over Cerium Oxide Catalyst

Comparative Study between 2‐Furonitrile and 2‐Cyanopyridine as Dehydrants in Direct Synthesis of Dialkyl Carbonates from CO₂ and Alcohols over Cerium Oxide Catalyst

Enabling New Approaches: Recent Advances in Processing Aliphatic Polycarbonate‐Based Materials

Rational Design of Heterogeneous Dual-Atom Catalysts for CO₂ Electroreduction Reactions

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Direct CO2 Transformation to Aliphatic Polycarbonates

Cited by 19 publications

References 100 publications

Comparative Study between 2‐Furonitrile and 2‐Cyanopyridine as Dehydrants in Direct Synthesis of Dialkyl Carbonates from CO2 and Alcohols over Cerium Oxide Catalyst

Comparative Study between 2‐Furonitrile and 2‐Cyanopyridine as Dehydrants in Direct Synthesis of Dialkyl Carbonates from CO2 and Alcohols over Cerium Oxide Catalyst

Enabling New Approaches: Recent Advances in Processing Aliphatic Polycarbonate‐Based Materials

Rational Design of Heterogeneous Dual-Atom Catalysts for CO2 Electroreduction Reactions

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Product

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Direct CO₂ Transformation to Aliphatic Polycarbonates

Comparative Study between 2‐Furonitrile and 2‐Cyanopyridine as Dehydrants in Direct Synthesis of Dialkyl Carbonates from CO₂ and Alcohols over Cerium Oxide Catalyst

Comparative Study between 2‐Furonitrile and 2‐Cyanopyridine as Dehydrants in Direct Synthesis of Dialkyl Carbonates from CO₂ and Alcohols over Cerium Oxide Catalyst

Rational Design of Heterogeneous Dual-Atom Catalysts for CO₂ Electroreduction Reactions