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Literature DB >> 33432206

An industrial perspective on catalysts for low-temperature CO₂ electrolysis.

Richard I Masel¹, Zengcai Liu², Hongzhou Yang², Jerry J Kaczur², Daniel Carrillo², Shaoxuan Ren³, Danielle Salvatore³, Curtis P Berlinguette³.

Abstract

Electrochemical conversion of CO2 to useful products at temperatures below 100 °C is nearing the commercial scale. Pilot units for CO2 conversion to CO are already being tested. Units to convert CO2 to formic acid are projected to reach pilot scale in the next year. Further, several investigators are starting to observe industrially relevant rates of the electrochemical conversion of CO2 to ethanol and ethylene, with the hydrogen needed coming from water. In each case, Faradaic efficiencies of 80% or more and current densities above 200 mA cm-2 can be reproducibly achieved. Here we describe the key advances in nanocatalysts that lead to the impressive performance, indicate where additional work is needed and provide benchmarks that others can use to compare their results.

Entities: Chemical

Year: 2021 PMID： 33432206 DOI： 10.1038/s41565-020-00823-x

Source DB: PubMed Journal: Nat Nanotechnol ISSN： 1748-3387 Impact factor: 39.213

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Cited

12 in total

1. The race to upcycle CO₂ into fuels, concrete and more.

Authors: Mark Peplow
Journal: Nature Date: 2022-03 Impact factor: 49.962

Review 2. Wet-chemical synthesis of two-dimensional metal nanomaterials for electrocatalysis.

Authors: Zijian Li; Li Zhai; Yiyao Ge; Zhiqi Huang; Zhenyu Shi; Jiawei Liu; Wei Zhai; Jinzhe Liang; Hua Zhang
Journal: Natl Sci Rev Date: 2021-08-11 Impact factor: 23.178

3. High current density electroreduction of CO₂ into formate with tin oxide nanospheres.

Authors: Thuy-Duong Nguyen-Phan; Leiming Hu; Bret H Howard; Wenqian Xu; Eli Stavitski; Denis Leshchev; August Rothenberger; Kenneth C Neyerlin; Douglas R Kauffman
Journal: Sci Rep Date: 2022-05-19 Impact factor: 4.996

4. Quantifying local pH changes in carbonate electrolyte during copper-catalysed [Formula: see text] electroreduction using in operando [Formula: see text] NMR.

Authors: Michael Schatz; Sven Jovanovic; Rüdiger-A Eichel; Josef Granwehr
Journal: Sci Rep Date: 2022-05-18 Impact factor: 4.996

5. Electroreduction of CO₂/CO to C₂ Products: Process Modeling, Downstream Separation, System Integration, and Economic Analysis.

Authors: Mahinder Ramdin; Bert De Mot; Andrew R T Morrison; Tom Breugelmans; Leo J P van den Broeke; J P Martin Trusler; Ruud Kortlever; Wiebren de Jong; Othonas A Moultos; Penny Xiao; Paul A Webley; Thijs J H Vlugt
Journal: Ind Eng Chem Res Date: 2021-11-30 Impact factor: 3.720

Review 6. Electrochemical CO₂ reduction - The macroscopic world of electrode design, reactor concepts & economic aspects.

Authors: Alina Gawel; Theresa Jaster; Daniel Siegmund; Johannes Holzmann; Heiko Lohmann; Elias Klemm; Ulf-Peter Apfel
Journal: iScience Date: 2022-03-04

Review 7. Electrochemical CO₂ reduction toward multicarbon alcohols - The microscopic world of catalysts & process conditions.

Authors: Theresa Jaster; Alina Gawel; Daniel Siegmund; Johannes Holzmann; Heiko Lohmann; Elias Klemm; Ulf-Peter Apfel
Journal: iScience Date: 2022-03-03

An industrial perspective on catalysts for low-temperature CO₂ electrolysis.

1. The race to upcycle CO₂ into fuels, concrete and more.

Review 2. Wet-chemical synthesis of two-dimensional metal nanomaterials for electrocatalysis.

3. High current density electroreduction of CO₂ into formate with tin oxide nanospheres.

4. Quantifying local pH changes in carbonate electrolyte during copper-catalysed [Formula: see text] electroreduction using in operando [Formula: see text] NMR.

5. Electroreduction of CO₂/CO to C₂ Products: Process Modeling, Downstream Separation, System Integration, and Economic Analysis.

Review 6. Electrochemical CO₂ reduction - The macroscopic world of electrode design, reactor concepts & economic aspects.

Review 7. Electrochemical CO₂ reduction toward multicarbon alcohols - The microscopic world of catalysts & process conditions.

Review 8. Electrochemical CO₂ Reduction on Cu: Synthesis-Controlled Structure Preference and Selectivity.

9. Active and conductive layer stacked superlattices for highly selective CO₂ electroreduction.

10. Energy comparison of sequential and integrated CO₂ capture and electrochemical conversion.

An industrial perspective on catalysts for low-temperature CO2 electrolysis.

1. The race to upcycle CO2 into fuels, concrete and more.

Review 2. Wet-chemical synthesis of two-dimensional metal nanomaterials for electrocatalysis.

3. High current density electroreduction of CO2 into formate with tin oxide nanospheres.

4. Quantifying local pH changes in carbonate electrolyte during copper-catalysed [Formula: see text] electroreduction using in operando [Formula: see text] NMR.

5. Electroreduction of CO2/CO to C2 Products: Process Modeling, Downstream Separation, System Integration, and Economic Analysis.

Review 6. Electrochemical CO2 reduction - The macroscopic world of electrode design, reactor concepts & economic aspects.

Review 7. Electrochemical CO2 reduction toward multicarbon alcohols - The microscopic world of catalysts & process conditions.

Review 8. Electrochemical CO2 Reduction on Cu: Synthesis-Controlled Structure Preference and Selectivity.

9. Active and conductive layer stacked superlattices for highly selective CO2 electroreduction.

10. Energy comparison of sequential and integrated CO2 capture and electrochemical conversion.

An industrial perspective on catalysts for low-temperature CO₂ electrolysis.

1. The race to upcycle CO₂ into fuels, concrete and more.

3. High current density electroreduction of CO₂ into formate with tin oxide nanospheres.

5. Electroreduction of CO₂/CO to C₂ Products: Process Modeling, Downstream Separation, System Integration, and Economic Analysis.

Review 6. Electrochemical CO₂ reduction - The macroscopic world of electrode design, reactor concepts & economic aspects.

Review 7. Electrochemical CO₂ reduction toward multicarbon alcohols - The microscopic world of catalysts & process conditions.

Review 8. Electrochemical CO₂ Reduction on Cu: Synthesis-Controlled Structure Preference and Selectivity.

9. Active and conductive layer stacked superlattices for highly selective CO₂ electroreduction.

10. Energy comparison of sequential and integrated CO₂ capture and electrochemical conversion.