Full atomistic reaction mechanism with kinetics for CO reduction on Cu(100) from ab initio molecular dynamics free-energy calculations at 298 K

Cheng, Tao; Xiao, Hai; Goddard, William A.

doi:10.1073/pnas.1612106114

Cited by 444 publications

(621 citation statements)

References 52 publications

Supporting

Mentioning

579

Contrasting

Unclassified

Order By: Relevance

“…Our previous QM metadynamics calculations with full solvent showed that a CO binding energy of 0.70 eV is sufficient to keep CO on the surface at potentials less negative than -0.91 V (RHE). 15 We find that this combination of binding sites reduces the *OCCOH formation energy to 0.52 eV, which is the best performance among the active surface sites investigated here.…”

Section: Introductionmentioning

confidence: 66%

“…24 In our recent work, we carried out full solvent QM based metadynamics to determine the RDS for C-C coupling, which we also found associated with the process of first electron transfer. 15,25 Consequently, we take the formation energy of *OCCOH as a descriptor to characterize the performance of surface sites toward C2 production. The experimental work of Verdaguer et al presented a correlation between strong CO binding sites and high CO reduction activity.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Nature of the Active Sites for CO Reduction on Copper Nanoparticles; Suggestions for Optimizing Performance

2017

Self Cite

View full text Add to dashboard Cite

Recent experiments show that the grain boundaries (GBs) of copper nanoparticles (NPs) lead to an outstanding performance in reducing CO2 and CO to alcohol products. We report here multiscale simulations that simulate experimental synthesis conditions to predict the structure of a 10 nm Cu NP (158 555 atoms). To identify active sites, we first predict the CO binding at a large number of sites and select four exhibiting CO binding stronger than the (211) step surface. Then, we predict the formation energy of the *OCCOH intermediate as a descriptor for C–C coupling, identifying two active sites, both of which have an under-coordinated surface square site adjacent to a subsurface stacking fault. We then propose a periodic Cu surface (4 by 4 supercell) with a similar site that substantially decreases the formation energy of *OCCOH, by 0.14 eV.

show abstract

Section: Introductionmentioning

confidence: 66%

Section: Introductionmentioning

confidence: 99%

Nature of the Active Sites for CO Reduction on Copper Nanoparticles; Suggestions for Optimizing Performance

2017

Self Cite

View full text Add to dashboard Cite

show abstract

“…Previous mechanistic studies revealed that the reaction pathways for CH 4 and C 2 H 4 differ at the bound CO* intermediate [48][49][50][51] .…”

Section: Nature Catalysismentioning

confidence: 99%

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

et al. 2018

View full text Add to dashboard Cite

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 ...

show abstract

“…[3][4][5][6] Synthesis of these products will by necessity require CÀHa nd CÀCb ond formation events.H owever,l ittle is understood about the processes taking place at the electrode surface.Specifically,in forming abond, two distinct surface-reaction mechanisms can be in play:surface-bound species can react with each other in what the heterogeneous catalysis field calls aL angmuir-Hinshelwood (LH) step or asurface-bound species can react with as pecies in solution in what is termed an Eley-Rideal (ER) step. [8] Insight into this mechanistic distinction is essential for the design of efficient CO 2 reduction catalysts.For example,inan ER mechanism leading to methane,s imply increasing the surface concentration of CO at the expense of Hadsorption is sufficient to promote higher-order product formation relative to H 2 evolution. Analogous mechanisms can be envisioned for CÀCbond formation leading to ethylene.…”

mentioning

confidence: 99%

“…[11][12][13][14][15][16] However,t hese studies alone are unable to parse reaction mechanisms.I ndeed, studies of the COdependent kinetics of higher-order product formation are uniquely suited to distinguish different mechanistic possibilities because they directly probe kinetically relevant intermediates and provide reaction orders for each product. [8,17,18] However,w hile excellent studies have investigated the pH, electrolyte cation, and crystal facet dependence of the reaction, [19][20][21][22][23][24][25][26][27][28][29] investigations of the CO-dependent kinetics have thus far been hampered by the low solubility of CO in aqueous electrolytes (1.1 mm), [30] which severely restricts the concentration range over which activation-controlled CO reduction kinetics can be probed. Furthermore,t he mechanistic regimes become distinguishable at near saturation CO coverage,t herefore requiring an experimental approach that fosters strong CO binding to the Cu surface.…”

mentioning

confidence: 99%

Competition between H and CO for Active Sites Governs Copper‐Mediated Electrosynthesis of Hydrocarbon Fuels

et al. 2018

View full text Add to dashboard Cite

The dynamics of carbon monoxide on Cu surfaces was investigated during CO reduction, providing insight into the mechanism leading to the formation of hydrogen, methane, and ethylene,t he three key products in the electrochemical reduction of CO 2 .Reaction order experiments were conducted at lowt emperature in an ethanol medium affording high solubility and surface-affinity for carbon monoxide.S urprisingly,the methane production rate is suppressed by increasing the pressure of CO,w hereas ethylene production remains largely unaffected. The data showthat CH 4 and H 2 production are linked through acommon Hintermediate and that methane is formed through reactions among adsorbed Hand CO,which are in direct competition with each other for surface sites.The data exclude the participation of solution species in ratelimiting steps,highlighting the importance of increasing surface recombination rates for efficient fuel synthesis.

show abstract

Full atomistic reaction mechanism with kinetics for CO reduction on Cu(100) from ab initio molecular dynamics free-energy calculations at 298 K

Cited by 444 publications

References 52 publications

Nature of the Active Sites for CO Reduction on Copper Nanoparticles; Suggestions for Optimizing Performance

Nature of the Active Sites for CO Reduction on Copper Nanoparticles; Suggestions for Optimizing Performance

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

Competition between H and CO for Active Sites Governs Copper‐Mediated Electrosynthesis of Hydrocarbon Fuels

Contact Info

Product

Resources

About