Grand canonical electronic density-functional theory: Algorithms and applications to electrochemistry

Sundararaman, Ravishankar; Goddard, William A.; Arias, T. A.

doi:10.1063/1.4978411

Cited by 252 publications

(310 citation statements)

References 60 publications

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“…This interfacial water geometry has been shown to be the most stable geometry for protonated, that is, acidic water bilayers, at the potentials of interest for HER. 47,[53][54][55] The reaction pathways are all performed at constant potential within a tolerance of 0.01 V, and the relevant energy comparison is therefore the energy at constant potential (often referred to as Ω [38][39][40][41][44][45][46][47][48][49]56 ),…”

Section: Methodsmentioning

confidence: 99%

A Challenge to the G ∼ 0 Interpretation of Hydrogen Evolution

2019

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Platinum is a nearly perfect catalyst for the hydrogen evolution reaction, and its high activity has conventionally been explained by its close-to-thermoneutral hydrogen binding energy (G∼0). However, many candidate non-precious metal catalysts bind hydrogen with similar strengths, but exhibit orders-of-magnitude lower activity for this reaction. In this study, we employ electronic structure methods that allow fully potential-dependent reaction barriers to be calculated, in order to develop a complete working picture of hydrogen evolution on platinum. Through the resulting ab initio microkinetic models, we assess the mechanistic origins of Pt's high activity. Surprisingly, we find that the G∼0 hydrogen atoms are kinetically inert, and that the kinetically active hydrogen atoms have ∆G's much weaker, similar to that of gold. These on-top hydrogens have particularly low barriers, which we compare to those of gold, explaining the high reaction rates, and the exponential variations in coverages can uniquely explain Pt's strong kinetic response to the applied potential. This explains the unique reactivity of Pt that is missed by conventional Sabatier analyses, and suggests true design criteria for non-precious alternatives.

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Section: Methodsmentioning

confidence: 99%

A Challenge to the G ∼ 0 Interpretation of Hydrogen Evolution

2019

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“…We computed the grand free energy at the constant electrochemical potential along with the implicit solvation model, in which the charged surfaces can be effectively screened by the ionic response in solution as implemented in JDFTx 8,21,22 . Computational details of JDFTx can be found in SI.…”

Section: Methodsmentioning

confidence: 99%

The Reaction Mechanism with Free Energy Barriers at Constant Potentials for the Oxygen Evolution Reaction at the IrO₂ (110) Surface

2016

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How to efficiently oxidize H 2 O to O 2 (Oxygen Evolution Reaction -OER) in photoelectrochemical cells (PEC) is a great challenge due to its complex charge transfer process, high overpotential, and corrosion. So far no OER mechanism has been fully explained atomistically with both thermodynamic and kinetics. IrO 2 is the only known OER catalyst with both high catalytic activity and stability in acidic conditions. This is important because PEC experiments often operate at extreme pH conditions. In this work we performed first principles calculations integrated with implicit solvation at constant potentials to examine the detailed atomistic reaction mechanism of OER at the IrO 2 (110) surface. We determined the surface phase diagram, explored the possible reaction pathways including kinetic barriers, and computed reaction rates based on the micro-kinetic models. This allowed us to resolve several long-standing puzzles about the atomistic OER mechanism.

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“…To obtain the energetics for electrochemical reactions, we used constantpotential method [21,22] as implemented in JDFTx code. [23] We used Garrity-Bennett-Rabe-Vanderbilt (GBRV) ultrasoft pseudopotentials, [24] with an energy cutoff of 20 Hartree, and the charge-asymmetric Small 2019, 15,1901899 www.small-journal.com nonlocally-determined local-electric (CANDEL) [25]…”

Section: Methodsmentioning

confidence: 99%

Eliminating Trap‐States and Functionalizing Vacancies in 2D Semiconductors by Electrochemistry

Shi

Zhao

Wang

et al. 2019

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One major challenge that limits the applications of 2D semiconductors is the detrimental electronic trap states caused by vacancies. Here using grand‐canonical density functional theory calculations, a novel approach is demonstrated that uses aqueous electrochemistry to eliminate the trap states of the vacancies in 2D transition metal dichalcogenides while leaving the perfect part of the material intact. The success of this electrochemical approach is based on the selectivity control by the electrode potential and the isovalence between oxygen and chalcogen. Motivated by these results, electrochemical conditions are further identified to functionalize the vacancies by incorporating various single metal atoms, which can bring in magnetism, tune carrier concentration/polarity, and/or activate single‐atom catalysis, enabling a wide range of potential applications. These approaches may be generalized to other 2D materials. The results open up a new avenue for improving the properties and extending the applications of 2D materials.

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Grand canonical electronic density-functional theory: Algorithms and applications to electrochemistry

Cited by 252 publications

References 60 publications

A Challenge to the G ∼ 0 Interpretation of Hydrogen Evolution

A Challenge to the G ∼ 0 Interpretation of Hydrogen Evolution

The Reaction Mechanism with Free Energy Barriers at Constant Potentials for the Oxygen Evolution Reaction at the IrO₂ (110) Surface

Eliminating Trap‐States and Functionalizing Vacancies in 2D Semiconductors by Electrochemistry

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Grand canonical electronic density-functional theory: Algorithms and applications to electrochemistry

Cited by 252 publications

References 60 publications

A Challenge to the G ∼ 0 Interpretation of Hydrogen Evolution

A Challenge to the G ∼ 0 Interpretation of Hydrogen Evolution

The Reaction Mechanism with Free Energy Barriers at Constant Potentials for the Oxygen Evolution Reaction at the IrO2 (110) Surface

Eliminating Trap‐States and Functionalizing Vacancies in 2D Semiconductors by Electrochemistry

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The Reaction Mechanism with Free Energy Barriers at Constant Potentials for the Oxygen Evolution Reaction at the IrO₂ (110) Surface