Enhanced electrocatalytic CO2 reduction via field-induced reagent concentration

Liu, Min; Pang, Yuanjie; Zhang, Bo; Luna, Phil De; Voznyy, Oleksandr; Xu, Jixian; Zheng, Xueli; Dinh, Cao-Thang; Fan, Fengjia; Cao, Changhong; Arquer, F. Pelayo Garcı́a de; Safaei, Tina Saberi; Mepham, Adam; Klinkova, Anna; Kumacheva, Eugenia; Filleter, Tobin; Sinton, David; Kelley, Shana O.; Sargent, Edward H.

doi:10.1038/nature19060

Cited by 1,473 publications

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“…It has been shown previously that sharp tips can improve bubble nucleation, concentrate stabilizing cations and exhibit high local fields, all of which increase current densities [27][28][29][30] . This high current density also promotes high local pH, limiting the protonation of bound CO that leads to methane formation 54 .…”

Section: Discussionmentioning

confidence: 99%

“…Furthermore, high-curvature structures, such as nanoneedles, promote nucleation of smaller gas bubbles 27 , and benefit from field-induced reagent concentration [28][29][30][31][32] , where high local negative electric fields concentrate positively charged cations to help stabilize CO 2 reduction intermediates 33 , enhancing CO 2 RR. However, combining high-curvature morphology with Cu + promotion to enable selective chemical conversion has yet to be explored.…”

Section: Articlesmentioning

confidence: 99%

“…To model ERD Cu, we constructed a mixed Cu:Cu 2 O slab with 25% Cu + species, closely matching the optimal amount of Cu + determined from sXAS studies. The ERD Cu(111) and ERD Cu(211) slabs serve as model systems for flat and high-curvature ERD Cu surfaces, respectively 28 . It was found that the Gibbs free energy of formation of the OCCOH* intermediate was lowest (1.13 eV) on the ERD Cu(211) system, 0.76 eV lower than the Cu(211) system, suggesting the presence of Cu + is favourable for ethylene production (Fig.…”

Section: Nature Catalysismentioning

confidence: 99%

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Catalyst electro-redeposition controls morphology and oxidation state for selective carbon dioxide reduction

et al. 2018

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As energy demand continues to increase, so too do anthropogenic carbon emissions and global temperatures. Renewable energy sources such as solar, wind and hydroelectricity displace fossil fuel carbon emissions and continue to progress to wider deployment. However, long-term (seasonal) energy storage remains a challenge that must be addressed for renewables to meet a major fraction of global energy demand 1 . Carbon dioxide electroreduction to renewable fuels and feedstocks provides an energy storage solution to the seasonal variability of renewable energy sources 2 . When coupled with carbon capture technology, the carbon dioxide reduction reaction (CO 2 RR) offers a means to close the carbon cycle.CO 2 RR electrocatalysts lower energetic barriers to CO 2 reduction by stabilizing intermediates and transition states in the multistep electrochemical reduction process 3 . Copper reduces CO 2 to a wide range of hydrocarbon products such as methane, ethylene, ethanol and propanol 4 . Unfortunately, bulk copper is not selective among various carbon products, and it also suffers Faradaic efficiency (FE) losses to the competing hydrogen evolution reaction.Among possible products, C2+ hydrocarbons are highly sought in view of their commercial value. Ethylene, for example, is a precursor to the production of polyethylene, a major plastic. Selectively producing ethylene over methane circumvents costly paraffin-olefin separation 5 . Developing catalysts that work at ambient conditions to produce C2 selectively over C1 gaseous products will increase the relevance of renewable feedstocks in the chemical sector.Oxide-derived copper is one class of catalyst that has shown enhanced CO 2 RR activity and increased selectivity towards multi-carbon products [6][7][8] . The selectivity of these catalysts is dependent on structural morphology and copper oxidation state 9-17 . Electrochemical reduction of copper oxide catalyst films can lead to grain boundaries, undercoordinated sites and roughened surfaces that are hypothesized to be catalytically active sites 8,18 . Residual oxides, proposed to play a key role in catalysis, may exist after electrochemical reduction 7 . A recent report of oxygen plasma-activated oxide-derived copper catalysts achieved an ethylene FE of 60% at − 0.9 V versus reversible hydrogen electrode (RHE) 9 , with activity attributed to the presence of Cu + species. In situ hard X-ray absorption spectroscopy (hXAS) experiments have suggested stable Cu + species exist at highly negative CO 2 RR potentials of ~− 1.0 versus RHE 9 . However, the presence of Cu + species during CO 2 RR is still the subject of debate; 7,19 and in situ tracking of the copper oxidation state with time resolution during CO 2 RR has remained elusive.Morphological effects of copper nanostructures have a significant effect on the selectivity of CO 2 RR to multi-carbon products [20][21][22][23][24] . Copper catalysts with different morphologies have been synthesized through annealing, chemical treatments on thin films, colloidal synthesis and ...

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Section: Discussionmentioning

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Section: Articlesmentioning

confidence: 99%

Section: Nature Catalysismentioning

confidence: 99%

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Catalyst electro-redeposition controls morphology and oxidation state for selective carbon dioxide reduction

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“…In fact, metal [86] was used to produce a nanoporous silver (np-Ag) catalyst able to reduce CO 2 electrochemically to CO in an efficient and selective way [87]. Nanostructuration of other metals such as gold was also studied both theoretically and practically, and it was proved that the increase of concentration of alkali cations due to manipulation of electric field allows an increase in electrocatalytic CO 2 reduction [88]. Another route is the production of formate/formic acid.…”

Section: Co 2 Conversion To Lower Oxidation Carbon Compoundsmentioning

confidence: 99%

The Virtuous CO₂ Circle or the Three Cs: Capture, Cache, and Convert

Bocchini

Castro²,

Cocuzza

et al. 2017

Journal of Nanomaterials

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It is not the first time in human history, nor will it be the last for that matter, that a collective problem calls for a collective response. Climate change fueled by greenhouse emissions affects humankind alike. Despite the disagreement among policymakers and scientists on the severity of the issue, the truth is that the problem remains. A broad look at different technologies being used today in different fields has led to the idea of bringing them together in an attempt to offer a viable solution to reducing anthropogenic CO 2 . The following paper describes how the nanotechnologies, available or soon to be available, would make CO 2 capture, cache, and conversion (coined the three Cs) a valid way for achieving a more sustainable energy society. Authors also set out to highlight with this work how knowledge transfer is instrumental in the development of technology and how methodical assessment of crossovers can expedite research when time plays against us.

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“…It has already been used to predict the results of quantum simulations to identify potential molecules and materials for flow batteries, organic light-emitting diodes 6 , organic photovoltaic cells and carbon dioxide conversion catalysts 7 . The algorithms can predict results in a few minutes, compared with the hundreds of hours it takes to run the simulations 8 .…”

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Luna¹,

Wei²,

Bengio³

et al. 2017

Nature

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Enhanced electrocatalytic CO2 reduction via field-induced reagent concentration

Cited by 1,473 publications

References 41 publications

Catalyst electro-redeposition controls morphology and oxidation state for selective carbon dioxide reduction

Catalyst electro-redeposition controls morphology and oxidation state for selective carbon dioxide reduction

The Virtuous CO₂ Circle or the Three Cs: Capture, Cache, and Convert

Use machine learning to find energy materials

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Enhanced electrocatalytic CO2 reduction via field-induced reagent concentration

Cited by 1,473 publications

References 41 publications

Catalyst electro-redeposition controls morphology and oxidation state for selective carbon dioxide reduction

Catalyst electro-redeposition controls morphology and oxidation state for selective carbon dioxide reduction

The Virtuous CO2 Circle or the Three Cs: Capture, Cache, and Convert

Use machine learning to find energy materials

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The Virtuous CO₂ Circle or the Three Cs: Capture, Cache, and Convert