Resonance-Promoted Formic Acid Oxidation via Dynamic Electrocatalytic Modulation

Gopeesingh, Joshua; Ardagh, M. Alexander; Shetty, Manish; Burke, Sean; Dauenhauer, Paul J.; Abdelrahman, Omar A.

doi:10.1021/acscatal.0c02201

Cited by 65 publications

(71 citation statements)

References 60 publications

(147 reference statements)

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“…(275) Other adsorbates such as CO, O, and OOH will be more sensitive to induced electric fields based on calculations for Pt(111); (276) this means that CATFETs show promise for a broad range of chemistries including the oxygen evolution reaction (OER), oxygen reduction reaction (ORR), CO oxidation, formic acid oxidation or decomposition, and methanol oxidation or decomposition. (50,(277)(278)(279) 3.8 Dynamic Ferroelectrics. Ferroelectrics, such as niobates, titanates, and zirconates (for example, BaTiO 3 , PbTiO 3 , SrTiO 3 and LiNbO 3 ), are materials that have a macroscopic polarization (electric dipole moment per unit volume) that can be switched by an applied electric field.…”

Section: Catalytic Field-effect Transistors (Catfet)mentioning

confidence: 99%

“…Development of linear scaling relationships that characterize the nature of stimuli are direct methods for making comparisons, (52,276,311) and microkinetic modeling (MKM) based on these relationships across different potential dynamic catalyst technologies will ultimately be the tool to predict new catalysts. (50,52) Examples of the opportunity provided by different stimuli can already be found in the application of strain and electric fields to transition metals. As shown in Figure 17a, comparison of the periodic trends for the adsorption of NH 2 * and NH* with the application of electric fields on Pt (111) surface both indicate positive scaling of NH2 * /NH * of 0.49 and 1.37, respectively.…”

Section: Evaluating Catalytic Stimulimentioning

confidence: 99%

“…As an example, an electrocatalysis system oscillating between 0 V and 0.6 V should compare the dynamic apparent turnover frequency with the steady state electrocatalytic rate at both 0 V and 0.6 V. This is demonstrated in Figure 12c, when a volcano versus applied voltage is observed for formic acid electro-oxidation on Pt with dynamic rates observed above all fixed-voltage conditions. (50) To claim oscillatory rate enhancement, the observed time-averaged dynamic production rate needs to exceed the steady state rates obtained at either operating endpoint. Finally, we urge caution in interpreting apparent activation energies (E a,app ) under dynamic catalytic conditions.…”

Section: Dynamic Catalysis Metrics: Efficiencymentioning

confidence: 99%

“…The paradigm of a dynamic catalysis changes the philosophy for catalyst synthesis and discovery and the strategy for utilizing a new temporal dimension for catalyst design. It has already been experimentally demonstrated that oscillating catalysts break the limits of static catalysts in the rate acceleration of electro-oxidation of formic acid (50) . But it is also possible that dynamic catalysts can change the mechanism for selecting individual reactions in a network (51) , while also altering catalyst operation in equilibrium-controlled reactions (52) .…”

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confidence: 99%

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The Catalytic Mechanics of Dynamic Surfaces: Stimulating Methods for Promoting Catalytic Resonance

et al. 2020

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Transformational catalytic performance in rate and selectivity is obtainable through catalysts that change on the time scale of catalytic turnover frequency. In this work, dynamic catalysts are defined in the context and history of forced and passive dynamic chemical systems, with classification of unique catalyst behaviors based on temporally-relevant linear scaling parameters. The conditions leading to catalytic rate and selectivity enhancement are described as modifying the local electronic or steric environment of the active site to independently accelerate sequential elementary steps of an overall catalytic cycle. These concepts are related to physical systems and devices that stimulate a catalyst using light, vibrations, strain, and electronic manipulations including electrocatalysis, back-gating of catalyst surfaces, and introduction of surface electric fields via solid electrolytes and ferroelectrics. These catalytic stimuli are then compared for capability to improve catalysis across some of the most important chemical challenges for energy, materials, and sustainability. File list (2) download file view on ChemRxiv Perspective_Manuscript_ChemRxiv.pdf (3.88 MiB) download file view on ChemRxiv Perspective_Supporting_Information_ChemRxiv.pdf (149.75 KiB)

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Section: Catalytic Field-effect Transistors (Catfet)mentioning

confidence: 99%

Section: Evaluating Catalytic Stimulimentioning

confidence: 99%

Section: Dynamic Catalysis Metrics: Efficiencymentioning

confidence: 99%

mentioning

confidence: 99%

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The Catalytic Mechanics of Dynamic Surfaces: Stimulating Methods for Promoting Catalytic Resonance

et al. 2020

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“…This Pd oxide layer can be removed by electrochemical reduction inducing the regeneration of the catalyst surface (Pd active sites) recovering the initial response for LA oxidation. This surface reactivation process has been previously exploited to increase the reaction rate and stability of Pd‐based catalysts for LA oxidation [32] and other reactions [67] . Galvanostatic curves were recorded at higher current densities (75–200 mA cm −2 ) to study the time‐dependent GA oxidation which also took place at very low potentials (Figure 6b) and significantly lower than those obtained for the LA oxidation.…”

Section: Resultsmentioning

confidence: 98%

Structure–Reactivity Effects of Biomass‐based Hydroxyacids for Sustainable Electrochemical Hydrogen Production

et al. 2021

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Biomass electro‐oxidation is a promising approach for the sustainable generation of H2 by electrolysis with simultaneous synthesis of value‐added chemicals. In this work, the electro‐oxidation of two structurally different organic hydroxyacids, lactic acid and gluconic acid, was studied comparatively to understand how the chemical structure of the hydroxyacid affects the electrochemical reactivity under various conditions. It was concluded that hydroxyacids such as gluconic acid, with a considerable density of C−OH groups, are highly reactive and promising for the sustainable generation of H2 by electrolysis at low potentials and high conversion rates (less than −0.15 V vs. Hg/HgO at 400 mA cm−2) but with low selectivity to specific final products. In contrast, the lower reactivity of lactic acid did not enable H2 generation at very high conversion rates (<100 mA cm−2), but the reaction was significantly more selective (64 % to pyruvic acid). This work shows the potential of biomass‐based organic hydroxyacids for sustainable generation of H2 and highlights the importance of the chemical structure on the reactivity and selectivity of the electro‐oxidation reactions.

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Hierarchical Design in Nanoporous Metals

et al. 2022

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Hierarchically porous metals possess intriguing high accessibility of matter molecules and unique continuous metallic frameworks, as well as a high level of exposed active atoms. High rates of diffusion and fast energy transfer have been important and challenging goals of hierarchical design and porosity control with nanostructured metals. This review aims to summarize recent important progress toward the development of hierarchically porous metals, with special emphasis on synthetic strategies, hierarchical design in structure-function and corresponding applications. The current challenges and future prospects in this field are also discussed.

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Resonance-Promoted Formic Acid Oxidation via Dynamic Electrocatalytic Modulation

Cited by 65 publications

References 60 publications

The Catalytic Mechanics of Dynamic Surfaces: Stimulating Methods for Promoting Catalytic Resonance

The Catalytic Mechanics of Dynamic Surfaces: Stimulating Methods for Promoting Catalytic Resonance

Structure–Reactivity Effects of Biomass‐based Hydroxyacids for Sustainable Electrochemical Hydrogen Production

Hierarchical Design in Nanoporous Metals

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