Electroreduction of CO<sub>2</sub> to CO Paired with 1,2-Propanediol Oxidation to Lactic Acid. Toward an Economically Feasible System

Pérez‐Gallent, Elena; Turk, Susan; Latsuzbaia, Roman; Bhardwaj, Rajat; Anastasopol, A.; Sastre, Francesc; Garcia, Amanda C.; Giling, Erwin; Goetheer, Earl

doi:10.1021/acs.iecr.8b06340

Cited by 44 publications

(31 citation statements)

References 32 publications

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“…save 1.25-times cost while AEM was used in a paired configuration at the same time. [90] Furthermore, Houache et al took glycerol electro-oxidation into consideration, achieving CO 2 RR and glycerol oxidation coelectrolysis. The CO was obtained from CO 2 RR over commercial Ag electrode, while formate was simultaneously gained from GOR with their as-prepared carbon supported Ni 1−x M x (M = Bi, Pd, and Au) electrocatalyst.…”

Section: Different Chemicals Co-generationmentioning

confidence: 99%

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Recent Advances on Electrolysis for Simultaneous Generation of Valuable Chemicals at both Anode and Cathode

Xiang

Peng

et al. 2021

Advanced Energy Materials

149

123

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Affected by both the energy shortage and environmental crisis, the development of electrocatalytic conversion process powered by renewable energy (wind, solar, tide, etc.) has received considerable attention. [1][2][3][4][5] Generally, electrocatalytic reactions involve To make efficient use of electrical energy in the whole electrocatalysis conversion process, the integrating of anode and cathode reactions plays a vital role. The combination of electrocatalytic anodic oxidation with cathodic reduction can not only maximize the return of energy investment, but also produces value-added materials on both sides. Herein, in this review, recent advances in co-electrolysis processes for valuable chemical production are systematically summarized. To be more specific, the popular hydrogen evolution reaction, carbon dioxide reduction reaction, nitrogen reduction reaction as well as nitrate reduction reaction integrated with anodic oxidation reactions to valueadded products, respectively are comprehensively reviewed, and then other paired electrolysis systems (especially for biomass-based compounds) toward high-value-added chemical generation are discussed in detail. This review sheds light on the integration of electrocatalytic reductions and oxidation reactions to develop high-value substances. To benefit researchers and facilitate the progress in this field, the challenges and future prospects for these integrated reactions are also proposed.

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Section: Different Chemicals Co-generationmentioning

confidence: 99%

mentioning

confidence: 99%

Recent Advances on Electrolysis for Simultaneous Generation of Valuable Chemicals at both Anode and Cathode

Xiang

Peng

et al. 2021

Advanced Energy Materials

149

123

View full text Add to dashboard Cite

show abstract

“…The concept of combining different anodic and cathodic important reactions can go beyond hydrogen production. Synthesis of CO via CO 2 electroreduction concomitant with production of lactic acid via 1,2‐propanediol electrooxidation was recently reported, highlighting the increased interest of the scientific community for generating new alternative processes based on renewable energy.…”

Section: Discussionmentioning

confidence: 99%

Prospects of Value‐Added Chemicals and Hydrogen via Electrolysis

et al. 2020

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Cost is a major drawback that limits the industrial‐scale hydrogen production through water electrolysis. The overall cost of this technology can be decreased by coupling the electrosynthesis of value‐added chemicals at the anode side with electrolytic hydrogen generation at the cathode. This Minireview provides a directory of anodic oxidation reactions that can be combined with cathodic hydrogen generation. The important parameters for selecting the anodic reactions, such as choice of catalyst material and its selectivity towards specific products are elaborated in detail. Furthermore, various novel electrolysis cell architectures for effortless separation of value‐added products from hydrogen gas are described.

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“…Its large overpotential and low product value are the intrinsic weaknesses of this reaction. Instead of applying appropriate catalysts to promote OER, alternative strategies have been proposed in replacing it with other oxidation reactions, mitigating overpotentials, and producing value‐added chemicals 134‐138 . Bevilacqua et al 137 combined CO 2 reduction and ethanol oxidation to acetate at cathode and anode (Figure 10B), respectively, providing a low working potential and hence a reduced energy consumption in contrast to the cell with OER, from 130 to 77 kWh.…”

Section: Design Of Concurrent Electrolysis Systemsmentioning

confidence: 99%

A brief review of electrocatalytic reduction of CO₂—Materials, reaction conditions, and devices

Pei

Zhong

Jin

2021

Energy Science & Engineering

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Global warming caused by the rapid increase in atmospheric CO2 concentration is regarded as one of the most serious problems faced by human being. Electrochemical CO2 reduction (ECR) is one promising strategy that can fix CO2 in a mild and clean manner combined with sustainable energies. However, the ECR performance is highly dependent on the catalysis system because of the difficulty in CO2 activation, low mass transfer, poor product selectivity, and competitive hydrogen evolution reaction (HER). The binding strength of electrocatalysts toward carbon intermediates is the crucial factor for ECR performance. Furthermore, the reaction conditions and the configurations of devices are also of significance for ECR efficiencies. Here, we briefly reviewed the effects of electrocatalyst materials, as well as the reaction conditions, coupled anodic reactions, and devices on the ECR. Moreover, challenges and some perspectives for large‐scale applications are included.

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Electroreduction of CO₂ to CO Paired with 1,2-Propanediol Oxidation to Lactic Acid. Toward an Economically Feasible System

Cited by 44 publications

References 32 publications

Recent Advances on Electrolysis for Simultaneous Generation of Valuable Chemicals at both Anode and Cathode

Recent Advances on Electrolysis for Simultaneous Generation of Valuable Chemicals at both Anode and Cathode

Prospects of Value‐Added Chemicals and Hydrogen via Electrolysis

A brief review of electrocatalytic reduction of CO₂—Materials, reaction conditions, and devices

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Electroreduction of CO2 to CO Paired with 1,2-Propanediol Oxidation to Lactic Acid. Toward an Economically Feasible System

Cited by 44 publications

References 32 publications

Recent Advances on Electrolysis for Simultaneous Generation of Valuable Chemicals at both Anode and Cathode

Recent Advances on Electrolysis for Simultaneous Generation of Valuable Chemicals at both Anode and Cathode

Prospects of Value‐Added Chemicals and Hydrogen via Electrolysis

A brief review of electrocatalytic reduction of CO2—Materials, reaction conditions, and devices

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Product

Resources

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Electroreduction of CO₂ to CO Paired with 1,2-Propanediol Oxidation to Lactic Acid. Toward an Economically Feasible System

A brief review of electrocatalytic reduction of CO₂—Materials, reaction conditions, and devices