CFD Modeling and Experimental Validation of an Alkaline Water Electrolysis Cell for Hydrogen Production

Rodríguez, Jesús López; Amores, Ernesto

doi:10.3390/pr8121634

Cited by 52 publications

(14 citation statements)

References 30 publications

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“…As shown by some works, thickness of bubble layer increases with the current density and bubbles adhered to catalyst surface cover most of catalyst surfaces and deteriorate their catalytic performance under HCD conditions. [ 73,74 ] Lu et al. synthesize MoS 2 catalysts with flat and nanostructured morphologies.…”

Section: Effect Of Current Density On Catalytic Performancementioning

confidence: 99%

Recent Advances in Design of Electrocatalysts for High‐Current‐Density Water Splitting

et al. 2022

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Electrochemical water splitting technology for producing "green hydrogen" is important for the global mission of carbon neutrality. Electrocatalysts with decent performance at high current densities play a central role in the industrial implementation of this technology. The field has advanced immensely in recent years, as witnessed by many types of catalysts have been designed and synthesized which work at industrially-relevant current densities (> 200 mA cm -2 ). Note that the activity and stability of catalysts can be influenced by their local reaction environment, which are closely related to the current density. By discussing recent advances in this field, we summarize several key aspects that affect the catalytic performance for high-current-density electrocatalysis, including dimensionality of catalysts, surface chemistry, electron transport path, morphology, and catalyst-electrolyte interplay. We highlight the multiscale design strategy that considers these aspects comprehensively for developing highcurrent-density catalysts. We also put forward out perspectives on the future directions in this emerging field.

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Section: Effect Of Current Density On Catalytic Performancementioning

confidence: 99%

Recent Advances in Design of Electrocatalysts for High‐Current‐Density Water Splitting

et al. 2022

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“…54,71 In this case, additional ohmic voltage losses due to the presence of gas bubbles have to be considered, as previously demonstrated in the multiphase fluid dynamics simulations of alkaline electrolyzers operating at high current density. 21,[72][73][74] Also, optical losses due to the presence of gas bubbles need to be considered when the illumination of the photoelectrodes occurs through the electrolyte layer, such as in tandem photoelectrochemical devices. 28,30,66 In order to fully exploit the bubble-induced convection, the abovementioned competing negative effects need to be quantified and carefully minimized depending on the target device configuration.…”

Section: Competing Effects Of Bubble Formationmentioning

confidence: 99%

Bubble-induced convection stabilizes the local pH during solar water splitting in neutral pH electrolytes

Obata

Abdi

2021

Sustainable Energy Fuels

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“…In the water softening process, bubbles are generated on the electrode surface due to the electrolysis of water. The efficiency of electrochemical processes is closely linked to the hydrodynamic of the bubble curtain (Rodríguez & Amores 2020). The solution convection caused by the drag effect of bubbles is the main mass transfer mode between electrodes.…”

Section: Introductionmentioning

confidence: 99%

Flow field characterization between vertical plate electrodes in a bench-scale cell of electrochemical water softening

Chen

Wang

et al. 2022

Water Science and Technology

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To analyze the effect of flow characteristics on electrochemical water softening, characteristics of flow fields in the vicinity of vertical plate electrodes in a bench-scale electrolysis cell for electrochemical water softening were visualized using particle image velocimetry technology, and the hardness drop values under different process conditions were measured. Properly increasing the current density or reducing the electrode spacing can increase the average flow velocity in the electrode gap. Excessive current density will cause bubble accumulation, form bubble vortex, interfere with the orderly flow of surrounding liquid and reduce mass transfer efficiency. When the electrode spacing is 120 mm, the highest water softening efficiency measured at the current density of 60 A/m2 is 16.56%. When the current density is 50 A/m2, the highest average speed measured at the electrode spacing of 60 mm is 0.00169 m/s, but the highest water softening efficiency measured at the electrode spacing of 90 mm is 23.3%.The circulation efficiency in the electrode gap of semi-closed structure is lower than that of free convection structure. The behavior of bubbles is the key to flow and mass transfer. It is important to consider its influence on bubble behavior when optimizing electrochemical parameters.

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CFD Modeling and Experimental Validation of an Alkaline Water Electrolysis Cell for Hydrogen Production

Cited by 52 publications

References 30 publications

Recent Advances in Design of Electrocatalysts for High‐Current‐Density Water Splitting

Recent Advances in Design of Electrocatalysts for High‐Current‐Density Water Splitting

Bubble-induced convection stabilizes the local pH during solar water splitting in neutral pH electrolytes

Flow field characterization between vertical plate electrodes in a bench-scale cell of electrochemical water softening

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