Practical Considerations for Continuum Models Applied to Surface Electrochemistry

Gauthier, Joseph A.; Dickens, Colin F.; Ringe, Stefan; Chan, Karen

doi:10.1002/cphc.201900536

Cited by 57 publications

(105 citation statements)

References 44 publications

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“…Geometry optimizations are conducted on symmetric slabs of four layers with the two central layers fixed. The symmetric cells are used to ensure a reliable determination of the workfunction if continuum solvation is applied 18 . To avoid interactions across periodic images, a vacuum spacing of 10 A on each side of the slab is included.…”

Section: A Computational Detailsmentioning

confidence: 99%

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Solvation at metal/water interfaces: An ab initio molecular dynamics benchmark of common computational approaches

Heenen

Gauthier

Kristoffersen

et al. 2020

The Journal of Chemical Physics

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132

151

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Section: A Computational Detailsmentioning

confidence: 99%

“…If not sampled consistently, the computed solvation energies may not be reliable 16 . Through the combination of static water bilayers with implicit/electrolyte models, a potential control can be introduced [17][18][19][20][21] . AIMD represent a highly accurate, but also a very computationally costly approach.…”

Section: Introductionmentioning

confidence: 99%

Solvation at metal/water interfaces: An ab initio molecular dynamics benchmark of common computational approaches

Heenen

Gauthier

Kristoffersen

et al. 2020

The Journal of Chemical Physics

Self Cite

132

151

View full text Add to dashboard Cite

show abstract

“…Second, no explicit ions have been used in the determination of the reaction barriers, hence we do not include any local interactions between ions and transition states that could potentially be present at the electrode-electrolyte interface. 71 Finally, the calculation of electrochemical barriers on the basis of grand-canonical DFT with a combination of implicit and explicit solvation is still a fairly new concept and further improvements and shortcomings of these methods have already been pointed out in previous work [72][73][74] .…”

Section: Discussion Of Discrepancies Between Theory and Experimentsmentioning

confidence: 99%

Using pH dependence to understand mechanisms in electrochemical CO reduction

Kastlunger

Wang

Govindarajan

et al. 2021

Preprint

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Electrochemical conversion of CO(2) into hydrocarbons and oxygenates is envisioned as a promising path towards closing the carbon cycle in modern technology. To this day, however, the reaction mechanisms towards the plethora of products are disputed, complicating the search for novel catalyst materials. In order to conclusively identify the rate-limiting steps in CO reduction on Cu, we analyzed the mechanisms on the basis of constant potential DFT kinetics and experiments at a wide range of pH values (3 - 13). We find that *CO dimerization is energetically favoured as the rate limiting step towards multi-carbon products. This finding is consistent with our experiments, where the reaction rate is nearly unchanged on an SHE potential scale, even under acidic conditions. For methane, both theory and experiments indicate a change in the rate-limiting step with electrolyte pH from the first protonation step in acidic/neutral conditions to a later one in alkaline conditions. We also show, through a detailed analysis of the microkinetics, that a surface combination of *CO and *H is inconsistent with the measured current densities and Tafel slopes. Finally, we discuss the implications of our understanding for future mechanistic studies and catalyst design.

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“…Second, no explicit ions have been used in the determination of the reaction barriers, hence we do not include any local interactions between ions and transition states that could potentially be present at the electrode-electrolyte interface. 66 Finally, the calculation of electrochemical barriers on the basis of grand-canonical DFT with a combination of implicit and explicit solvation is still a fairly new concept and further improvements and shortcomings of these methods have already been pointed out in previous work 65,67,68 .…”

Section: Dft Simulations and Kinetic Modelling Suggest The Formation Of C2+ Products Through Co Dimerization Is Favored Over A Later Coupmentioning

confidence: 99%

Using pH dependence to understand mechanisms in electrochemical CO reduction

Kastlunger

Wang

Govindarajan

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

Electrochemical conversion of CO(2) into hydrocarbons and oxygenates is envisioned as a promising path towards closing the carbon cycle in modern technology. To this day, however, the reaction mechanisms towards the plethora of products are disputed, complicating the search for novel catalyst materials. In order to conclusively identify the rate-limiting steps in CO reduction on Cu, we analyzed the mechanisms on the basis of constant potential DFT calculations and experiments at a wide range of pH values (3 - 13). We find that *CO dimerization is energetically favoured as the rate limiting step towards multi-carbon products. This finding is consistent with experiments, where the reaction rate is nearly unchanged on an SHE potential scale, even under acidic conditions. For methane, both theory and experiments indicate a change in the rate-limiting step with electrolyte pH from the first protonation step in acidic/neutral conditions to a later one in alkaline conditions. We also show, through a detailed analysis of the microkinetics, that a surface combination of *CO and *H is inconsistent with the measured current densities and Tafel slopes. Finally, we discuss the implications of our understanding for future mechanistic studies and catalyst design.

show abstract

Practical Considerations for Continuum Models Applied to Surface Electrochemistry

Cited by 57 publications

References 44 publications

Solvation at metal/water interfaces: An ab initio molecular dynamics benchmark of common computational approaches

Solvation at metal/water interfaces: An ab initio molecular dynamics benchmark of common computational approaches

Using pH dependence to understand mechanisms in electrochemical CO reduction

Using pH dependence to understand mechanisms in electrochemical CO reduction

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