The Nucleation Rate of Single O<sub>2</sub> Nanobubbles at Pt Nanoelectrodes

Soto, Álvaro Moreno; German, Sean R.; Ren, Hang; Meer, Devaraj van der; Lohse, Detlef; Edwards, Martin A.; White, Henry S.

doi:10.1021/acs.langmuir.8b01372

Cited by 67 publications

(62 citation statements)

References 42 publications

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“…Henry's solubility constant KH is a decreasing function of temperature T specific to each liquid-gas pair. 31,32,33,34 In electrochemical processes, nucleation takes place when the concentration of dissolved gas near the electrode surface C0, becomes large enough (see Figure 2). For simplicity, in what follows, we will consider the case when only a single gas species is present.…”

Section: Nucleationmentioning

confidence: 99%

Influence of Bubbles on the Energy Conversion Efficiency of Electrochemical Reactors

Angulo

Linde

Gardeniers

et al. 2020

Joule

523

374

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Bubbles are known to influence energy and mass transfer in gas evolving electrodes. However, we lack a detailed understanding on the intricate dependencies between bubble evolution processes and electrochemical phenomena.This review discusses our current knowledge on the effects of bubbles on electrochemical systems with the aim to identify opportunities and motivate future research in this area. We first provide a base background on the physics of bubble evolution as it relates to electrochemical processes. Then we outline how bubbles affect energy efficiency of electrode processes, detailing the bubble-induced impacts on activation, ohmic and concentration overpotentials.Lastly, we describe different strategies to mitigate losses and how to exploit bubbles to enhance electrochemical reactions. Context & ScaleElectrochemical reactors will play a key role in the electrification of the chemical industry and can enable the integration of renewable electricity sources with chemical manufacturing. Most large-scale industrial electrochemical processes, including chloro-alkali and aluminum production, involve gas evolving electrodes. The evolution of bubbles at the surface of redox reaction sites often lead to the reduction of the active electrode area, the increase of ohmic resistance in the electrolyte and the formation of undesirable concentration gradients. All of these effects result in energy losses which reduce the efficiency of electrochemical systems. This review synthesizes our current understanding on the relationship between bubble evolution and energy losses in electrochemical reactors. By presenting a thorough account on the state of the research in this area, we aim to provide a common ground for the research community to improve our understanding on the complex processes involved in multiphase electrochemical systems. Increasing our knowledge on the relationship between bubbles and electrochemistry will lead to new strategies to mitigate and exploit bubble-induced phenomena leading to design guidelines for high-performing electrochemical reactors.

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Section: Nucleationmentioning

confidence: 99%

Influence of Bubbles on the Energy Conversion Efficiency of Electrochemical Reactors

Angulo

Linde

Gardeniers

et al. 2020

Joule

523

374

View full text Add to dashboard Cite

show abstract

“…We have taken some first steps to answer these questions [159][160][161][162]. Figure 22a shows catalytically grown oxygen bubbles on a platinum surface immersed in a hydrogen peroxide (H 2 O 2 ) solution.…”

Section: From Surface Nanobubbles To Catalysis and Electrolysismentioning

confidence: 99%

Bubble puzzles: From fundamentals to applications

Lohse

2018

Phys. Rev. Fluids

Self Cite

143

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For centuries, bubbles have fascinated artists, engineers, and scientists alike. In spite of century-long research on them, new and often surprising bubble phenomena, features, and applications keep popping up. In this paper I sketch my personal scientific bubble journey, starting with single bubble sonoluminescence, continuing with sound emission and scattering of bubbles, cavitation, snapping shrimp, impact events, air entrainment, surface micro-and nanobubbles, and finally coming to effective force models for bubbles and dispersed bubbly two-phase flow. In particular, I also cover various applications of bubbles, namely in ultrasound diagnostics, drug and gene delivery, piezo-acoustic inkjet printing, immersion lithography, sonochemistry, electrolysis, catalysis, acoustic marine geophysical survey, and bubble drag reduction for naval vessels, and show how these applications crossed my way. I also try to show that good and interesting fundamental science and relevant applications are not a contradiction, but mutually stimulate each other in both directions.

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“…This is linked to the buildup of proton concentration close to the electrode surface under the PIM-1 coating. The overall mechanism can be written as excitation (2), charge separation (3), hole quenching (4), hydrogen evolution (5), and transport of molecular hydrogen to the electrode for discharge (6).…”

Section: Photoelectrocatalytic Processes Enhanced By Pim Membranesmentioning

confidence: 99%

“…Electrochemical reactions often are associated with phase formation, multi‐phase systems, or phase boundaries: gas evolution, gas consumption, liquid‐liquid based interfaces and/or droplets with a triple phase boundary reaction zone, nucleation of bubbles or solid particles, or collisions of solid particles with the electrode surface . The interaction and reactivity of particles, droplets, or bubbles changes with distance from the electrode surface and with interface design.…”

Section: Introduction To Triphasic Electrocatalysismentioning

confidence: 99%

Polymers of Intrinsic Microporosity in Triphasic Electrochemistry: Perspectives

et al. 2019

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Polymers of intrinsic microporosity (PIMs) as molecularly rigid polymers have emerged as a new class of gas‐permeable glassy materials. They offer excellent processability and a range of potential applications also in electrochemical processes. Particularly interesting is the ability of some PIM films to remain gas‐permeable/binding even in the presence of (aqueous) liquid electrolyte to give triphasic interfacial reactivity. Gaseous reagents or products (such as hydrogen or oxygen) are bound probably into hydrophobic regions in the wet PIM film to avoid macroscopic bubble formation and to enhance both the surface reactivity and the apparent activity of the gas solute close to the electrode/catalyst surface. The photoelectrochemical formation of hydrogen gas close to a platinum electrode is enhanced by PIM‐1, which is presented as an example of energy harvesting through molecular H2 “energy carrier” transport.

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The Nucleation Rate of Single O₂ Nanobubbles at Pt Nanoelectrodes

Cited by 67 publications

References 42 publications

Influence of Bubbles on the Energy Conversion Efficiency of Electrochemical Reactors

Influence of Bubbles on the Energy Conversion Efficiency of Electrochemical Reactors

Bubble puzzles: From fundamentals to applications

Polymers of Intrinsic Microporosity in Triphasic Electrochemistry: Perspectives

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The Nucleation Rate of Single O2 Nanobubbles at Pt Nanoelectrodes

Cited by 67 publications

References 42 publications

Influence of Bubbles on the Energy Conversion Efficiency of Electrochemical Reactors

Influence of Bubbles on the Energy Conversion Efficiency of Electrochemical Reactors

Bubble puzzles: From fundamentals to applications

Polymers of Intrinsic Microporosity in Triphasic Electrochemistry: Perspectives

Contact Info

Product

Resources

About

The Nucleation Rate of Single O₂ Nanobubbles at Pt Nanoelectrodes